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Regional trade of medicinal plants has facilitated the retention of traditional knowledge: case study in Gilgit-Baltistan Pakistan.

Author information

Affiliations

  • 1. Key Laboratory for Plant Diversity and Biogeography of East Asia, Kunming Institute of Botany, Chinese Academy of Sciences, Kunming, 650201, Yunnan, China.
      Authors
    • Salim MA 1
    • Ranjitkar S 1
    • Xu J 1
    (3 authors)
  • 2. Missouri Botanical Garden, Post Office Box 299, St. Louis, MO, 63166, USA.
      Authors
    • Hart R 2
    (1 author)
  • 3. Department of Biological Sciences, Karakorum International University, Gilgit, Gilgit-Baltistan, Pakistan.
      Authors
    • Khan T 3
    • Ali S 3
    • Kiran C 3
    • Parveen A 3
    • Batool Z 3
    • Bano S 3
    (6 authors)

ORCIDs linked to this article

Journal of Ethnobiology and Ethnomedicine, 28 Jan 2019, 15(1):6
https://doi.org/10.1186/s13002-018-0281-0 PMID: 30691476 PMCID: PMC6348662

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Abstract 

Background

The ethnic groups in Gilgit-Baltistan have been utilizing local resources in their centuries-old traditional healing system. Most tribes within these ethnic groups still rely on traditional healing systems. We aim to understand the current status, uses, and abundance of medicinal plants, associated traditional knowledge, and trade.

Materials and methods

The study incorporated over 300 local community members (70% men and 30% women) in focused group discussions, semi-structured interviews, and homework assignments for 8th to 12th grade students to document traditional knowledge (TK) in six districts in Northeast Pakistan. We calculated various indices such as informant consensus factor, use value, relative frequency of citation, and CoKriging. These indices, along with repetitively used medicinal plants, were used to analyze differences in studied locations.

Results

Most of the community members still rely on traditional medication in the study areas. However, we found the highest number of medicinal plants used in Skardu and Gilgit compared to other districts and these two districts also represent trade centers and a highly populated area regarding medicinal plants. Results indicate connection amongst the surveyed villages signifying mixing of knowledge from different sources, with certain areas more influenced by traditional Chinese medicine and others more by Ayurveda and Unani.

Conclusion

TK is mostly retained with elder community members; however, those directly linked with market value chain retain rich knowledge on traditional use of the medicinal plants from the region. Major trade centers in the region also coincide with a high density of medicinal plant occurrence, knowledge, and higher utilization. Therefore, with the increasing trade in medicinal plant in the region, there is potential for rejuvenation of this knowledge and of plant use in the region.

Free full text 

Logo of jenthobmedLink to Publisher's site
J Ethnobiol Ethnomed. 2019; 15: 6.
Published online 2019 Jan 28. https://doi.org/10.1186/s13002-018-0281-0
PMCID: PMC6348662
PMID: 30691476

Regional trade of medicinal plants has facilitated the retention of traditional knowledge: case study in Gilgit-Baltistan Pakistan

Muhammad Asad Salim,1,2 Sailesh Ranjitkar,1,3 Robbie Hart,4 Tika Khan,5 Sajid Ali,5 Chandni Kiran,5 Asma Parveen,5 Zahra Batool,5 Shanila Bano,5 and Jianchu Xucorresponding author1,3
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Associated Data

Supplementary Materials
Data Availability Statement

Abstract

Background

The ethnic groups in Gilgit-Baltistan have been utilizing local resources in their centuries-old traditional healing system. Most tribes within these ethnic groups still rely on traditional healing systems. We aim to understand the current status, uses, and abundance of medicinal plants, associated traditional knowledge, and trade.

Materials and methods

The study incorporated over 300 local community members (70% men and 30% women) in focused group discussions, semi-structured interviews, and homework assignments for 8th to 12th grade students to document traditional knowledge (TK) in six districts in Northeast Pakistan. We calculated various indices such as informant consensus factor, use value, relative frequency of citation, and CoKriging. These indices, along with repetitively used medicinal plants, were used to analyze differences in studied locations.

Results

Most of the community members still rely on traditional medication in the study areas. However, we found the highest number of medicinal plants used in Skardu and Gilgit compared to other districts and these two districts also represent trade centers and a highly populated area regarding medicinal plants. Results indicate connection amongst the surveyed villages signifying mixing of knowledge from different sources, with certain areas more influenced by traditional Chinese medicine and others more by Ayurveda and Unani.

Conclusion

TK is mostly retained with elder community members; however, those directly linked with market value chain retain rich knowledge on traditional use of the medicinal plants from the region. Major trade centers in the region also coincide with a high density of medicinal plant occurrence, knowledge, and higher utilization. Therefore, with the increasing trade in medicinal plant in the region, there is potential for rejuvenation of this knowledge and of plant use in the region.

Electronic supplementary material

The online version of this article (10.1186/s13002-018-0281-0) contains supplementary material, which is available to authorized users.

Keywords: Ethnomedicine, Ethnoecology, Medicinal plants, Traditional knowledge, Trade in medicinal plants, Gilgit-Baltistan

Introduction

Gilgit-Baltistan, the northeast mountainous region of Pakistan, is outstanding for its rich ethnic diversity [13]. This region is situated in a strategic geographical location that is important as a part of the ancient silk route and its position along the China-Pakistan Economic Corridor [35]. For centuries, knowledge exchange has occurred between indigenous dwellers and migrants and peddlers from the southern, northern, and western parts of Asia. Besides, the region is one of the important plant areas in the Himalaya, Karakoram, and Hindukush (HKH) landscape [612]. In the epoch of Anthropocene, as for other parts of the world, this region also experienced problems due to human population growth and associated land use transformation that severely affected both important species and the wider ecosystem [1315]. Still natural resources, especially plant diversity, are very significant for ethnic communities in this mountainous landscape [10, 14, 16, 17]. Plants are the source of energy and food, a building material for houses, and a main component of the health care system as folklore medicine [1827].

There are about 600 species of flowering plants in Pakistan that are utilized as medicinal plants and around 500 of these have global significance and studies available [9, 16, 28]. Around 50,000 traditional healers and informal Pansaris (retailers) are registered in Pakistan who frequently utilize and sell 400–600 plants species for their medicinal, cultural, traditional, and spiritual benefits [2931]. Gilgit-Baltistan, with above 300 reported species of MAPs, is a hotspot for medicinal plants and their utilization in Pakistan [9, 1214, 16, 27, 30, 3241]. With seven districts and an ideal mountainous landscape, this region is naturally suitable for high-value medicinal plants. The local communities have been utilizing this resource for many generations [9, 12, 15, 33, 36, 4245]. Several researchers have previously documented traditionally used medicinal plant from different districts in this region. Shedayi and Gulshan (2012) and Shedayi et al. (2014) in Ghizer district; Khan et al. (2013) and Akhtar et al. (2016) in Hunza; Bano et al. (2014) in Skardu; Khan and Khatoon (2007) and Fahad and Bano (2012) in Gilgit; Abbas et al. (2016) in Baltistan and the contributions of Hussain et al. (2011), Khan et al. (2011), Qureshi et al. (2006), and Ali et al. (2017) are important and noteworthy for the documentation of plant species used locally for medicinal purposes besides reporting on the modes of their uses and diseases targeted/cured through traditional herbal practitioners.

In addition to the utilization of medicinal plants in the traditional healing system, trade in herbal raw material and product is not new in the area. As this region serves as an ancient trade route that connects south Asia with China, Central Asia, and West Asia; trade in medicinal plants and exchange of traditional healing knowledge is very likely. For instance, archeological studies reveal the influence of cultural incursions from the Indian subcontinent, China, Scythia (Eurasia), Transoxiana (Uzbekistan, Tajikistan, southern Kyrgyzstan, and southwest Kazakhstan), and Ancient Greece, amongst others on traditional medicinal system [3, 46]. Before the introduction of Islam, the communities in Gilgit-Baltistan were predominantly practicing Buddhism [3, 4650]. The region is recognized for its contributions towards survival and expansion of Ayurveda during the British regime [51]. Hakim Ajmal Khan is a famous Indian physician who worked for the revival of Ayurveda and Unani systems during the British era by establishing an Ayurveda and Unani medical college and a pharmaceutical company besides continuing with his own clinical practice of the systems [52]. Before the region completely came under Dogra Raj of the Kashmir State, Hunza, Gilgit, Nagar, and Ghizer mainly remained under Chinese influence, whereas Skardu, Astore, Ghanche, and Diamer remained under Tibetan influence [3, 46]. Recently, with development of the Karakoram Highway (KKH) and China-Pakistan Economic Corridor (CPEC) that follow the ancient Silk Routes [3, 50] in the region, this area has become important junction of trade.

Our research provides the first comparative study for six districts of Gilgit-Baltistan where the influence of Chinese, Ayurveda, Unani, and Tibetan healing systems on folk knowledge has been observed. Traditional knowledge of medicinal plants is often socially integrated through communal learning and intercultural exchange. Medicinal plants in mountainous terrain are known for their distribution in elevation corridors or endemism to a particular locality. We therefore aim to explore the richness of traditional knowledge of medicinal plants, their uses, distribution, and trade in the mountainous region of Gilgit-Baltistan, learn about the knowledge exchange between the old and young generation as well as amongst different communities and localities of the region, and how medicinal systems like Chinese, Ayurveda, Tibetan, and Unani influenced the use of traditional medicine system in the region. We also explore the possible factors behind the general decline in knowledge about medicinal plants, yet the continued use of traditional medicine for treatment of different diseases and how the current markets and market players supplement this phenomenon. We take an inventory of these plants, their use value, and local importance at a regional level and current markets. We also look at how these factors and the influence of different medicinal systems in the region compliment the transfer of knowledge to younger generations and across different ethnicities and locations in the region.

Materials and methods

Study area

Gilgit-Baltistan is located in the far north of Pakistan, with Afghanistan to the north and west, China to the north and east, and India to the south [8]. The seven districts are spread over an area of 72,496 km2. The region is rugged and mountainous, located amongst three of the highest mountain ranges—the Himalayas, the Karakoram, and the Hindukush (HKH) and home to the largest number of glaciers outside the polar region [36, 53, 54].

The study was focused on Gilgit, Hunza, Nagar, Ghizer, Skardu, and Astore Districts of Gilgit-Baltistan. The residents are divided into sub-groups based on their origin as well as their ethno-linguistic clustering (Fig. 1). Yashkun, Sheen/Shinaki, Wakhi (those who migrated from Wakhan), Burushos, Dom, Brokpa, and Balti are the main tribes of the area; some Kashmiris, Kohistani, Mongols, Mughals, Rajas, Pathans, Gujar, Soniwal, Mon, Hor, and Kashgari also reside here [35, 5560]. The majority of Gilgit-Baltistan is sparsely populated with these tribes, but Ghizer is dominated by Burushos; Gilgit, Hunza, and Nagar have Burushos, Sheen, and Yashkun; Diamer and Astore are majorly populated by Sheen, Yashkun, and Kohistani communities; and Skardu and Ghanche are predominantly Mon, Hor, and Mongols [60, 61]. The languages spoken by Burushos, Sheen, and Yashkun are Shina, Burushaski, Wakhi, and Khowar (only Ghizer and parts of Hunza) while the Mongols, Mon, and Hor speak Balti [9, 38, 60, 62].

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Area map showing vegetative cover, settlements, center of major ethno-linguistic clusters, and surveyed areas in Gilgit-Baltistan

Communities in Gilgit-Baltistan are dependent on agricultural resources and live close to the forest area (Fig. 1). Land cover changes, lack of resource management and sustainable harvesting policies, and political interests at massive scale in the HKH and Pamir mountain ranges have severe and long-lasting impacts on the region [6366]. Medicinal plants and traditional medication have been used for generations for curing different diseases [34, 36, 63, 67]. Since opening of KKH in 1982 [4], markets for local products started to develop, thus exerting pressure on natural resources [33, 68].

Ethnobotanical survey

The study was carried out from January 2017 to May 2018, during which 300+ local community members were approached via focused group discussions (FGDs), semi-structured interviews, and homework assignments for 8th to 12th Grade school and college students. The participants included men and women community members, local traditional health practitioners (THPs), community elders, and wholesalers and retailers of medicinal plants. Following the snowball sampling methodology [6974], a total of 15 FGDs and 240 individual interviews were conducted for data collection. Sixty students were provided with a set of questionnaires to reach their families and understand what kind of plants/herbal remedies are used in the families and how traditional knowledge is preserved within a family. This method was tested in Nepal and was quite effective to document traditional knowledge [75]. Prior permission and consent for data collection and publication was obtained from all the participants. The homework assignments for school students were administered under the supervision of concerned class teachers. Data on age and gender was also acquired from the participants. These methods resulted in data covering an ethnobotanical inventory of plants, part used, therapeutic utilities, the location and timing of acquiring the resource, and the existing markets with trade opportunities. The initial taxonomic identification of medicinal plants was done by a taxonomist in the field [7678] and by cross-referencing photographs, voucher specimens, and the local name of species with previously available material and literature from the study area [9, 35, 41, 79, 80]. Information on local names of plant species, and parts of the plant utilized for different medicinal purposes was recorded. Collected specimens were mounted on herbarium sheets and identified by the taxonomists in the Karakoram International University. The voucher specimens were authenticated through the plant list (www.theplantlist.org), tropicos (www.tropicos.org), and flora of Pakistan (www.efloras.org) and deposited in the herbarium of the Karakoram International University.

Quantitative analysis

We regressed age of participants against the number of species reported by respective age group and people engaged in the trade of medicinal plants during the survey to understand TK in the region. We used CoKriging method [81] to interpolate the number of species recorded and used in various medical conditions from the surveyed locations to recognize section of highest medicinal plant use in the region. Kriging is an advanced geostatistical procedure that generates an estimated surface from a scattered set of points with z values. CoKriging is multivariate extension of Kriging method that uses information from one or more correlated variables measured in the same range. This method is useful in mountainous areas with rugged terrain. This method has been tested and used in tree richness mapping, abundance mapping, and recognizing areas at high risk of species invasion [8183].

We calculated quantitative measures like informant consensus factor (ICF), use value (UV), and relative frequency of citation (RFC) for medicinal plants based on 208 illnesses categorized into 29 ailment groups from each district in the survey. The illnesses were categorized based on a particular part of the body affected or particular illnesses for multiple parts of the body. For example, all kinds of skin illnesses were categorized under skin infections while diseases related to stomach and intestinal disorders were grouped into stomach and intestine category (further detail is available in Additional files 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, and 12). A brief description of the quantitative measures is provided below:

Informant consensus factor (ICF)

The ICF was calculated to find a consensus between participants on the reported treatments for each set of diseases [79, 84, 85]. ICF was calculated using given formula [79, 86, 87];

ICF=NurNtNur1

where Nur indicates the number of use reports for a specific disease category and Nt mentions the number of taxa used for the disease category.

Use value (UV)

Use value determines the quantitative measure for relatively important local plant species [78, 8789]. The use value is calculated using the following formula:

UV=UiN

where∑Ui is the total number of use reports for a given species and N is the total number of participants inquired for the species.

Relative frequency of citation (RCF)

Ethno medicinal data was quantitatively analyzed using RFC which indicated the local importance of medicinal species. The RFC was calculated using given formula [87, 89, 90]:

RFC=FCN0<RFC<1

where FC is the number of participants reporting on the use of a plant species and N is the total number of participants in the survey.

Discriminant analysis (DA)

We used discriminant analysis to delimit the geographical differences of the ethnobotanical knowledge using quantitative measures (viz. UV and RCF), highly used species, and number of treatments. Discriminant function analysis or discriminate analysis (DA) determines naturally occurring groups and the variables responsible for segregating amongst them [9193].

Results and discussion

Demographic features of the participants

More than 300 participants including 70% men and 30% women were interviewed during the survey (Fig. (Fig.2).2). The Yashkun, Sheen/Shinaki, Burushos, Wakhi, and Balti communities approached during the survey possessed good knowledge on medicinal plants use. Although these tribes maintain individual identities representing different parts of the mountainous region, the cross-cultural interactions have led to the growth and diversification of the traditional knowledge. The results from FGDs, HH, and market surveys revealed that regardless of ethnicity, THPs and retailers retain a significant level of information on the medicinal plants of the region, the locations from where the plants can be acquired and the ailments they can be utilized for. Although the participants from the community and THPs provided more extensive information than the retailers, when it came to the question of how to use a certain plant as medicine, the retailers had ample information to share on a higher number of medicinal plants and their general uses (Fig. 3 Fig. 4a). We found that participants above 50 years of age had significant traditional knowledge regarding utilization of medicinal plants. This was evident from the number of species and their uses reported per interview where a higher number of species was reported by participants above 50 years of age. Our results from the linear regression (R2 = 0.65; p < 0.0001) also revealed that number of species reported increase with age of the participant (Fig. 4b). The students responding to homework assignments mostly brought information from women representatives of the household, thus providing relevant information on which plant species are kept at home and used for treating common sicknesses.

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a Comparison of medicinal plant species highest occurrence and uses in Gilgit-Baltistan region. b Linear regression showing relation of age and number of plant species reported. Legend TK = participants and Trade = retailers and traditional healers

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Section of the highest use and occurrence of medicinal plants and uses in Gilgit-Baltistan region

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Grouping survey sites in Gilgit-Baltistan based on the medicinal plants and their use reports

Taxonomic diversity

We documented a total of 231 species representing 141 genera and 61 families (Table 2). Compositae was the most dominant family with 30 (12.9%) species reported, followed by Leguminosae, Lamiacceae, Rosaceae, Polygonaceae, Ranunculaceae, Salicaceae, Apiaceae, and Berberidaceae, with 16 (6.9%), 15 (6.5%), 15 (6.5%), 14 (6.1), 10 (4.3%), 10 (4.3%), 9 (3.9%), and 9 (3.9%) species, respectively. In total, 208 diseases were treated with documented species. The herbaceous flora accounts for 64% of the total reported species followed by shrubs at 20%, trees at 13%, and grasses at 3% (Fig. (Fig.5).5). Figure Figure66 represents the percentages of uses of different parts of the medicinal plants (further detail is available in Additional files 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, and 12 where a comprehensive list of species is provided besides the district level analysis).

Table 2

RFC, UV, number of uses, and ailments of species from each location

S no.FamilySpeciesLocal namePart used (Kargha-K, Nagar-N, Skardu-S, Ghizer-Gh, Hunza-H, Astore-A, Gilgit-G)Mode of use (Kargha-K, Nagar-N, Skardu-S, Ghizer-Gh, Hunza-H, Astore-A, Gilgit-G)Location (Astore-Astore, Ghizer-Ghizer, Gojal-Gojal, Central Hunza-Hunza, Jalalabad-Jalalabad, Kargha-Kargha, Nagar-Nagar, Skardu-Skardu)Average of RFCAverage of UVAilment categoriesNo. of use responsesVoucher no.Previous citation
1AmaranthaceaeAerva lanata (L.) Juss.ShutpaskWhole plantAsh (H, N, K, Gh, A), decoction (S, A, Gh, H, K)Gojal0.1750.214286314MAS-08917
2Achyranthes aspera L.larghakyFlowerPasteKargha0.20.176471317MAS-23840, 41
3Chenopodium album L.Snew, Sheleet, KunoawLeaf (S), whole plant (H, GhPaste, infusion, poultice, decoctionGhizer, Gojal, Hunza, Skardu0.218750.136706859MAS-121, MAS-153, MAS-4579, 12, 13, 17, 33, 37
4Dysphania botrys (L.) Mosyakin & ClemantsKhama, KhordAerial (K), whole plant (S, H)Powder, decoctionGojal, Jalalabad, Skardu0.1944440.12619757MAS-128, MAS-229, MAS-48235
5Amaranthus viridis L.DhimdoLeafPaste, directKargha, Nagar0.10.333333310MAS-314, MAS-37614
6Allium humile KunthChungBulbInfusion, directSkardu0.2666670.176471317MAS-38112, 13, 17
7Allium carolinianum DC.Kachpauk, Booma, ChongBulb (K, S, A), leaf, bulb (H)Paste (S), direct, decoctionAstore, Gojal, Kargha, Nagar, Skardu0.2050.2298821102MAS-012, MAS-112, MAS-346, MAS-42412, 13, 17
8Allium cepa L.Ghashoo, Xong, SongBulb (K), leaf, bulb (S), poultice, bulb (H)Poultice, decoction, direct (H, S, Gh, N, K), paste (S, A, K, Gh)Hunza, Kargha, Nagar, Skardu0.168750.202381950MAS-179, MAS-305, MAS-365, MAS-4899, 33, 38, 39
9Allium sativum L.Zgoqpa, BukpaBulbDirectHunza, Kargha, Nagar, Skardu0.318750.11036711149MAS-180, MAS-306, MAS-366, MAS-4909, 33, 39
10AnacardiaceaePistacia mutica Fisch. & C.A.Mey.DaraawBranchesOilHunza0.20.14285717MAS-1379, 33
11Pistacia khinjuk stocksKakavomnGalls, resin, wood, leafDirect, decoctionJalalabad0.1750.071429684MAS-20315
12ApiaceaeHeracleum candicans Wall. ex DC.GhangLeafDecoctionSkardu0.2666670.071429114MAS-39212
13Pimpinella diversifolia DC.KohniodWhole plantPowder, decoctionAstore, Kargha, Skardu0.2694440.15960MAS-028, MAS-270, MAS-44013
14Pleurospermum candollei (DC.) C.B. Clarke in Hook. f.BraqshundunWhole plantDecoctionAstore, Skardu0.350.142857214MAS-037, MAS-44913
15Angelica glauca EdgewChoro, ChoraRoot (K), stem, seed, root (Gh)Decoction, powder, directGhizer, Kargha0.2166670.1666671055MAS-078, MAS-28411, 16
16Carum carvi L.Filizooh, Zera, HayyoSeed (K, S), seed, fruit (Gh)Decoction, powder, direct (Gh)Ghizer, Kargha, Skardu0.2055560.139184866MAS-084, MAS-290, MAS-47211, 12, 16
17Daucus carota L.Phopuce, Jangli, Jut Ghachoon, Ghasoon, Gholafuvi lonaLeaf, seed (H, N), leaf (S)Direct, decoctionHunza, Kargha, Nagar, Skardu0.2916670.134921757MAS-181, MAS-307, MAS-367, MAS-4919, 32, 33
18Coriandrum sativum L.Ausu, NaskiSeedDecoction, directHunza, Kargha, Skardu0.2138890.119929441MAS-183, MAS-309, MAS-4939, 33, 39
19Foeniculum vulgare Mill.BadianFruit (K), seed (S)DecoctionKargha, Skardu0.23750.099206225MAS-326, MAS-51138, 39
20Heracleum pinnatum C.B. ClarkeHltireetLeafDirectKargha, Skardu0.2958330.142857214MAS-328, MAS-51339
21AsteraceaeAllardia tomentosa Decne.TarkhamLeaf, flowerGrindedSkardu0.20.230769313MAS-38039
22 Leontopodium leontopodinum NaqposhotoSeedDecoctionKargha, Skardu0.3416670.098086441MAS-329, MAS-51439
23BerberidaceaePodophyllum emodi Wall. ex Hook.f. & ThomsonShingoyRoot, rhizomeDecoctionKargha0.20.2210MAS-24511, 53
24Berberis pseudumbellata R.ParkerIshkeen, Shokurum, SkyurbooRoot, stem, bark (K), whole plant (S), flower, fruit, seed (A)Decoction, powderAstore, Jalalabad, Kargha, Skardu0.3250.11421310111MAS-019, MAS-220, MAS-261, MAS-43113, 15, 19, 27, 34, 39
25Berberis lycium RoyleZolg, Ishkeen, SkyurbooRoot, leaf, seed, bark, fruit, flower (S, K, N), root, leaf, fruit (H), root, leaf, stem, fruit (Gh)DecoctionGhizer, Gojal, Hunza, Kargha, Nagar, Skardu0.3222220.09253255743MAS-061, MAS-118, MAS-351, MAS-4549, 14, 16, 17, 32, 33, 34, 37, 38
26Berberis brandisiana AhrendtIshkeen, IshkenachiRoot, stem, barkDecoctionJalalabad, Kargha, Nagar, Skardu0.331250.11499839490MAS-235, MAS-312, MAS-374, MAS-49715, 34
27Berberis orthobotrys Bien. ex Aitch.Ishkeen,SkyurbooRoot, stem, bark (K), root, stem (SDecoctionJalalabad, Kargha, Skardu0.3416670.11244415121MAS-236, MAS-313, MAS-49815, 34
28Berberis parkeriana C.K.Schneid.Ishkeen,SkyurbooRoot, stemDecoctionKargha, Skardu0.3541670.154762533MAS-317, MAS-50234
29Berberis stewartiana JafriIshkeen, ShokurumRoot, leafDecoctionKargha, Skardu0.250.224599628MAS-318, MAS-50334
30Berberis ulicina Hook.f. & ThomsonIshkeen, ShokurumRoot, leafDecoctionKargha, Skardu0.26250.204861525MAS-319, MAS-50434
31Berberis vulgaris L.Ishkeen, ShokurumFruit (S), leaf, fruit (K)Decoction, directKargha, Skardu0.3041670.154762639MAS-320, MAS-50512, 34, 39
32BetulaceaeBetula utilis D.DonXuxi, Halli, Jowzee, Furze, StaqpaBark, wood (N, K, H), bark (S)Decoction, directGojal, Hunza, Jalalabad, Kargha, Nagar, Skardu0.23750.09955413143MAS-123, MAS-167, MAS-225, MAS-4779, 11, 13, 15, 17, 39, 53
33BoraginaceaeOnosma hispida Wall. ex G. DonKangmarWhole plantDecoctionAstore, Kargha0.2916670.162338532MAS-020, MAS-26211, 13
34BrassicaceaeBrassica oleracea var. botrytis L.Phul GobiFlowerDirectHunza0.1750.16666716MAS-1329
35Descurainia sophia (L.) Webb ex PrantlKhashirWhole plantPowder, decoctionAstore, Skardu0.2333330.174242423MAS-034, MAS-44613
36Raphanus sativus L.Moolo, Gholafuvi sonmaLeafDirectHunza, Kargha, Nagar, Skardu0.28750.071584599MAS-182, MAS-308, MAS-368, MAS-4929, 39
37Brassica oleracea var. capitata L.Band GobiFlowerDirectHunza, Nagar0.150.133333216MAS-186, MAS-3699
38Brassica juncea (L.) Czern.Sarsung marSeedOilKargha, Skardu0.1916670.142857214MAS-323, MAS-50839
39Lepidium latifolium L.SonmaLeaf (K), leaf, root (S)Powder, infusion (S)Kargha, Skardu0.33750.171429422MAS-330, MAS-51512
40BuxaceaeBuxus papillosa C.K. SchneidAngarooLeafOilSkardu0.2333330.083333112MAS-38838
41CampanulaceaeCodonopsis clematidea (Schrenk) C.B.ClarkeLoo sunma/Bajo mindoqFlowerAstore, Skardu0.3666670.107143221MAS-032, MAS-44412, 13
42CannabinaeaeCannabis sativa L.ThoonchSeed (N, H), whole plant (K)DirectHunza, Kargha, Nagar0.2583330.13276212101MAS-178, MAS-304, MAS-3649, 14, 33, 53
43CapparaceaeCapparis spinosa L.Kraba, Kavir, Kappar, Chopir, Shorot, Champarrang, ThoonchRoot, bark, fruit, seed, branches, flower (N, K), root, fruit, seed (S), seed, flower, fruit (H)Oil (H, N, K), powder, decoction, oil (S), paste (H)Gojal, Hunza, Jalalabad, Kargha, Nagar, Skardu0.2763890.09359925302MAS-124, MAS-226, MAS-359, MAS-4789, 12, 15, 17, 33, 37, 38, 39, 53
44CaprifoliaceaeLonicera microphylla Willd. ex Schult.PushkarStem, brnaches, fruitPasteJalalabad0.20.043478123MAS-19915
45Valeriana wallichii DC.Mushk-balaRoot (K, H), rhizomes (S)Powder, decoction, pasteGojal, Kargha, Skardu0.2666670.149335640MAS-130, MAS-300, MAS-48411, 17, 38
46Lonicera asperifolia Hook. f. & ThomsonKrrabaLeafDirectKargha, Skardu0.2708330.142857214MAS-331, MAS-51639
47CaryophyllaceaeCerastium fontanum Baumg.BlogharWhole plantDirectAstore, Kargha, Skardu0.2222220.118276654MAS-024, MAS-266, MAS-43613
48Compositae Anaphalis nepalensis ChikeeFlower, fruitDried flower, powder, fume (Gh)Ghizer0.2333330.14285717MAS-03916
49Artemisia annua L.XoonWhole plantDirectGhizer0.2333330.157895319MAS-04037
50Artemisia dubia Wall. Ex Bess.BursayWhole plantPaste, powderGhizer0.20.142857321MAS-04137
51Artemisia herba-alba AssoKho BursayWhole plantDecoctionGhizer0.20.272727311MAS-04237
52Saussurea heteromalla (D.Don) Hand.-MazzKali ziraWeedPaste, directGhizer0.10.111111218MAS-04916
53Anaphalis triplinervis (Sims) Sims ex C.B.ClarkeYeepwooshLeaf, flowerPoultice, dried leaf and flowerGojal0.2250.166667424MAS-09017
54Tragopogon dubius ScopKreel wooshFlowerDecoctionGojal0.150.14285717MAS-10417
55Achillea millefolium L.YarrowFlowerDecoction, poulticeKargha0.1750.142857321MAS-23740, 41
56Artemisia laciniata Willd.KhampaLeafPasteKargha0.30.14285717MAS-23911, 12
57Artemisia rutifolia Spreng. Ex SprengKho BursayAerialPasteKargha0.1750.14285717MAS-24038
58Artemisia fragrans WilldKho BursayAerialPowderSkardu0.2666670.16666716MAS-38438
59Artemisia santolinifolia Turcz. Ex Krasch.Kho BursayLeaf, stemPowder, pasteSkardu0.2666670.2210MAS-38539
60Jurinea dolomiaea Boiss.SathingLeaf, rootDecoction, poulticeSkardu0.2333330.214286314MAS-39312
61Pseudognaphalium luteoalbum (L.) Hilliard & B. L. BurttThliriLeafDecoctionSkardu0.3666670.14285717MAS-40412
62Senecio chrysanthemoides DC.Api mindoqLeaf, flower, rootDecoction, poulticeSkardu0.2333330.157895319MAS-40912
63Tanacetum senecionis (Jacquem. ex Besser) J.Gay ex DC.Hilteree/TialoFlowerPowder, infusion, decoctionSkardu0.40.166667318MAS-41138
64Taraxacum officinale (L.) Weber ex F.H.Wigg.Doduli, Mamo Shikinachi, Ishkanachi, Shantha, Talkhting, KhosmasLeaf, root (K, Gh), leaf, flower (S), leaf, latex (H), latex (A)Decoction, powder (K), infusion (S)Astore, Ghizer, Gojal, Hunza, Kargha, Skardu0.2222220.16119818136MAS-003, MAS-051, MAS-4159, 13, 14, 16, 17, 33, 37, 38, 53
65Artemisia brevifolia WallRooner, Bursay, Taroqtpesk, BustaeLeaf (N, K), leaf, flower (S, H), whole plant (A,Gh)Poultice, directAstore, Ghizer, Gojal, Kargha, Nagar, Skardu0.2166670.2187591262MAS-006, MAS-054, MAS-109, MAS-41813, 17, 35, 37, 38, 39
66Artemisia maritima L.Rooner, Zoon, BursayLeaf, bud, flower (N, K, Gh), aerial (H), flower (A)Direct, paste, decoction (Gh)Astore, Ghizer, Hunza, Kargha, Nagar, Skardu0.2708330.11261918228MAS-007, MAS-055, MAS-142, MAS-4199, 11, 14, 16, 33, 37, 39, 40, 41, 53
67Artemisia sieversiana Ehrh.Hampa, KhampaLeaf (K, A, N), leaf, flower, root (S)Infusion, decoction, pasteAstore, Kargha, Nagar, Skardu0.1833330.20211629MAS-022, MAS-264, MAS-349, MAS-43412, 39
68Cousinia thomsonii C.B.ClarkeCharchuFlowerDiretAstore, Skardu0.2666670.142857214MAS-033, MAS-44513
69Carthamus tinctorius L.Pock, PoongFlower, seedDecoction, oilGhizer, Hunza0.3708330.07982814175MAS-066, MAS-154, MAS-4599, 16, 32, 33, 37
70Echinops echinatus Roxb.JacheerWhole plantDecoction, directGhizer, Hunza, Kargha, Nagar0.2604170.103175696MAS-072, MAS-160, MAS-281, MAS-3569, 14, 16
71Saussurea lappa (Decne.) Sch.Bip.MinalRoot (K), stem, root (Gh)Powder, paste, decoctionGhizer, Kargha0.2041670.139959975MAS-082, MAS-28811, 16, 37, 53
72Artemisia scoparia Waldst. & Kitam.KhobustaeLeaf, flower (K, S), whole plant (Gh)Paste, fume (Gh), decoction (S)Ghizer, Kargha, Skardu0.2027780.176667643MAS-083, MAS-289, MAS-47113, 37
73Cichorium intybus L.Ishkinachi, Caroop, qarali ChicknachiWhole plant (N, K), root, leaf (S)Direct, infusion, decoction, decoction (H)Gojal, Hunza, Kargha, Nagar, Skardu0.2516670.1487981299MAS-126, MAS-297, MAS-360, MAS-48012, 14, 17, 33
74Tanacetum gracile Hook.f. & ThomsonCerpho bursay, serfo bursay, BursayLeafDecoction, powder (S), directHunza, Kargha, Skardu0.2527780.155844532MAS-185, MAS-311, MAS-49512, 39, 40, 41
75Artemisia absinthium L.ZoonWhole plantInfusion, paste, powderKargha, Nagar0.1750.177778424MAS-315, MAS-3779, 11, 14
76Seriphidium brevifolium (Wall. ex DC.) Ling & Y.R.LingBursayLeaf (K), flower (S)Powder, decoction, directKargha, Skardu0.3208330.142857214MAS-336, MAS-52112, 39
77Tanacetum falconeri Hook.f.Haltiry, Htialo, Pholing, Zoon, TyaloWhole plant (K), leaf (S)Direct, powderKargha, Skardu0.2041670.190909421MAS-338, MAS-52313, 39
78ConvolvulaceaeCanvolvulus arvensis L.ThringthringmoWhole plantDecoction, powderAstore, Kargha, Skardu0.1972220.166667318MAS-023, MAS-265, MAS-43513
79Cuscuta reflexa Roxb.Ghbul thaqStem, flower (K), whole plant (S)Decoction, direct (S)Kargha, Skardu0.23750.1625426MAS-325, MAS-51038, 39
80CrassulaceaeRhodiola imbricata Edgew.ChundolRootPowderSkardu0.2333330.222222418MAS-40612
81CucurbitaceaeCupressus sempervirens L.SaroFruit, stemDecoction, directGhizer0.4666670.095238221MAS-04416, 37
82Citrullus vulgaris Schrad.BowarFruitDecoctionHunza0.2250.045455122MAS-1339, 33
83Cucurbita pepo L.HosarSeedOil, directNagar0.40.085714335MAS-3399
84CupressaceaeJuniperus squamata Buch.Cheleh, Chili, Hlashuk, Yarz, ShukpaFruit, twigsInfusion, oil, pasteGhizer0.2333330.132075753MAS-04537
85Juniperus turkestanica Kom.ChelehLeaf, fruit, woodPowder, decoctionJalalabad0.1750.054054237MAS-19815
86Juniperus excelsa M.Bieb.Cheleh, Chili, Hlashuk, Yarz, ShukpaFruit, wood, leaf (N, K, H), fruit (S, A)Ash, powder, decoction, paste (Gh)Astore, Ghizer, Gojal, Jalalabad, Kargha-Kargha, Nagar, Skardu0.2452380.15746525194MAS-004, MAS-052, MAS-107, MAS-41612, 13, 14, 15, 16, 17, 37
87Juniperus communis L.Mitthary, OshukFruit, wood (K, A, S), fruit, wood, oil (Gh)Infusion, decoction, paste, powder (A)Astore, Ghizer, Jalalabad, Skardu0.2729170.14511413112MAS-009, MAS-057, MAS-215, MAS-42113, 15, 37
88ElaeagnaceaeElaeagnus rhamnoides (L.) A.NelsonBuru, Buroh, Seabuckthorn, Soq, Rema, Zakh, Chanso, KarsoqLeaf, fruit, seed, root, wood (K, N), leaf, fruit, seed (S), fruit (H), fruit, stem, leaf (Gh), fruit, leaf (A)Ash, direct, decoction, powderAstore, Ghizer, Gojal, Hunza, Jalalabad, Kargha, Nagar, Skardu0.3239580.10693843747MAS-002, MAS-050, MAS-105, MAS-4149, 11, 12, 13, 14, 15, 17, 30, 33, 38, 39, 53
89Elaeagnus angustifolia L.Shekarkuch, Gindawar, Ghonair, Sisk, GhundairWhole plant (N, K), flower, fruit, gum (Gh, H)Direct, powder, decoction,Ghizer, Gojal, Hunza, Jalalabad, Kargha, Nagar0.2958330.08055525331MAS-059, MAS-116, MAS-350, MAS-4529, 14, 15, 16, 17, 32, 33, 37
90EphedraceaeEphedra intermedia Schrenk & C.A.Mey.Shaay SoomStem, rootDecoctionJalalabad0.20.061538465MAS-19457
91Ephedra gerardiana Wall. ex StapfSoom, Say, Yemook, Sopat, SoptWhole plant (K, Gh), aerial (S), leaf, stem (H)DecoctionGhizer, Gojal, Hunza, Jalalabad, Kargha, Skardu0.2944440.09794122239MAS-060, MAS-275, MAS-4539, 11, 12, 14, 15, 16, 32, 33, 37, 38, 53
92EquisetaceaeEquisetum arvense L.Thangshingy harswa, Thangshing stwaAerial (S), whole plant (A)DecoctionAstore, Skardu0.2833330.142857214MAS-035, MAS-44713, 38
93EricaceaeRhododendron anthopogon D. DonChaumanLeaf, flowerInfusion, decoctionSkardu0.30.15320MAS-40712
94GentianaceaeSwertia petiolata D. DonBramaLeaf, rootPaste, decoction, powder (A)Skardu0.2333330.210526419MAS-41012
95Gentiana olivieri Griseb.TiktaLeaf, flower (K), leaf (S)DirectKargha, Skardu0.2333330.162338318MAS-327, MAS-51212, 39
96GeraniaceaeGeranium nepalense SweetBamikFruit, rootPoultice, decoction, powderSkardu0.30.235294417MAS-39112
97GrossulariaceaeRibes himalense Royle ex Decne.MurshatoohFruitPowderJalalabad0.1750.075340MAS-20415
98Ribes orientale Desf.GhonashatoohRootPowderJalalabad0.20.033333260MAS-20515
99Ribes alpestre Wall. ex Decne.Shumlooh, SkioruruRoot, flowerPowder, directAstore, Gojal, Jalalabad, Skardu0.1895830.1098219109MAS-011, MAS-111, MAS-217, MAS-42313, 15, 17
100Iridaceae Crocus sativus L. ZafranFlowerPowderKargha, Skardu0.2666670.142857214MAS-324, MAS-50939
101Juglandaceae Juglans regia L. Achow, AshoohRoot, kernel, wood (N), root, kernel, seed, wood (K), kernel (S, H)Oil, directHunza, Jalalabad, Kargha, Nagar, Skardu0.2766670.09853611139MAS-173, MAS-301, MAS-4889, 13, 15, 33
102LamiaceaeNepeta floccosa Benth.BuzlanjLeaf, flowerDecoction, infusionGojal0.20.172414529MAS-09817
103Isodon rugosus (Wall. ex Benth.) CoddPhaypushLeaf, branchesPowderJalalabad0.20.097561441MAS-19715
104Dracocephalum nuristanicum Rech.f. & Edelb.ShamdunLeaf, flower, seedPaste, decoction, infusionSkardu0.70.064935577MAS-38912, 38, 39
105Mentha haplocalyx Briq.ShomaLeafDirect, pasteSkardu0.30.214286314MAS-39439
106Nepeta leucolaena Benth. ex Hook.f.AskutaWhole plantPowder, decoctionSkardu0.3666670.035714128MAS-39512, 38
107Prunella vulgaris L.HarswaLeafDecoctionSkardu0.4666670.153846426MAS-40312
108Mentha royleana Wall. ex Benth.Foling, GudunjLeaf (K, A, S), leaf, flower (H)Powder, paste (H), direct, infusionAstore, Gojal, Kargha, Skardu0.2916670.104499991MAS-013, MAS-113, MAS-257, MAS-42512, 13, 17, 38, 39
109Thymus linearis Benth.Tumuro, Tumburu, TumburukWhole plant (N, S), leaf, flower (H), flower (A)Decoction, infusionAstore, Gojal, Nagar, Skardu0.2229170.10051412151MAS-014, MAS-114, MAS-347, MAS-42612, 13, 17, 53
110Mentha longifolia (L.) L.Fileel, Whadan, PhileelLeaf, flower (H, K, N), leaf (Gh)Powder, paste, decoction (Gh)Ghizer, Gojal, Kargha, Nagar0.2520830.1251429319MAS-065, MAS-122, MAS-278, MAS-35314, 16, 17
111Mentha sylvestris L.BundooLeaf, flowerDecoctionGhizer, Hunza0.2416670.101515874MAS-067, MAS-155, MAS-4609, 33, 37, 53
112Thymus serphyllum L.Tumuro, Ree tumburukWhole plant (K, Gh), leaf, flower (S), aerial (H)DecoctionGhizer, Hunza, Kargha, Skardu0.331250.07951217268MAS-074, MAS-162, MAS-283, MAS-4679, 11, 14, 16, 33, 37, 38
113Mentha arvensis L.PeenoLeaf (S, K), whole plant (Gh)Powder, direct, pasteGhizer, Kargha, Skardu0.2750.138889644MAS-085, MAS-291, MAS-47337, 38, 39
114Perovskia abrotanoides Kar.Faring bursayFlowerInfusionHunza, Kargha, Skardu0.2027780.126246657MAS-184, MAS-310, MAS-49412, 39, 40, 41
115Mentha spicata L.PodinaWhole plantDecoctionHunza, Nagar0.33750.0468018160MAS-189, MAS-3729, 33
116Stachys tibetica VatkeKhampaLeafPowder, directKargha, Skardu0.3041670.049043241MAS-337, MAS-52239
117LeguminosaeAstragalus frigidus (L.) A.GrayShashalLeaf, stemPowderAstore0.2333330.176471317MAS-00113
118Astragalus falconeri BungeHapochoLeaf, stemPowderGhizer0.2333330.083333112MAS-04316
119Melilotus officinalis (L.) Pall.BissasingWhole plantDecoctionGhizer0.3333330.115385652MAS-04616, 37
120Astragalus strictus Benth.Zhop/ThopeLeaf, flowerDirectGojal0.1750.14285717MAS-09117
121Melilotus alba Ledeb.SinjhiAerialPasteGojal0.1750.166667212MAS-09617
122Caragana brevifolia Kom.HapoochoRootDirect, decoctionJalalabad0.1750.058824117MAS-19115
123Caragana tragacanthoides var. himalaica KomarovHapoochoRootDirect, decoctionJalalabad0.2250.037037127MAS-19215
124Robinia pseudoacacia L.KekarResin, wood, legumesPasteJalalabad0.350.076923226MAS-20615
125Astragalus zanskarensis BungeShukpaLeaf, stemPaste, ashSkardu0.20.2528MAS-38639
126Trifolium fragiferum L.Gul-e-NasreenLeaf, flowerDirectSkardu0.2333330.142857214MAS-41338
127Trifolium pratense L.Chita-batta, Ol, Jangli shaftalFlowerPowderAstore, Hunza, Kargha, Skardu0.21250.078571676MAS-017, MAS-147, MAS-260, MAS-4299, 13, 14, 40, 41
128Cicer microphyllum Benth.StranjungstwaWhole plantAstore, Kargha, Skardu0.2305560.087446335MAS-025, MAS-267, MAS-43713
129Medicago sativa L.Ucharg, IshfitWhole plantDirect, powder, decoctionGhizer, Gojal0.20.134921970MAS-058, MAS-11516, 17, 37
130Sophora mollis (Royle) BakerKhakhul, Popshing, PushoolLeaf (K, Gh), leaf, seed (S), whole plant (H)paste, powder, decoction (S)Ghizer, Gojal, Hunza, Kargha, Skardu0.2433330.1085710108MAS-119, MAS-151, MAS-277, MAS-4559, 12,16, 17, 38, 39
131Glycyrrhiza glabra L.ShalakoRoot, rhizome (Gh), rhizome (K)Decoction, pasteGhizer, Kargha0.30.09195412145MAS-079, MAS-28511, 16, 37
132Trigonella foenum-graecum L.ShamilikLeaf (K), whole plant (S, Gh)Direct, decoctionGhizer, Kargha, Skardu0.2777780.111683662MAS-086, MAS-292, MAS-47437, 38, 39
133Astragalus psilocentros Fisch.BiowaCharchu, Biacharchoo, Sokhrus, HapoochoLeaf, stem (K, H), leaf, root, thorny branches (S),Decoction, infusion (S)Ghizer, Hunza, Kargha, Skardu0.2583330.153501963MAS-088, MAS-166, MAS-294, MAS-4769, 12, 13, 38
134LinaceaeLinum usitatissimum L.HumanSeedPowderHunza0.1750.0787410127MAS-1349, 32, 33
135LythraceaePunica granatum L.Danooh, Sio, Dolum, DanuFruit, root (K, S), flower, fruit, seed, bark (H)Decoction, paste, powder, directGojal, Hunza, Jalalabad, Skardu0.268750.11252419220MAS-125, MAS-169, MAS-227, MAS-4799, 15, 17, 33, 38
136MalvaceaeMalva neglecta Wallr.ShanishahWhole plantPowder, decoctionGojal0.1250.071429114MAS-09517
137Abelmoschus esculentus (L.) MoenchBhindiSeed, fruitInfusionHunza, Jalalabad, Nagar0.3083330.064052357MAS-174, MAS-233, MAS-3629
138Morus nigra L.Kini MaroochWhole plantDecoction, paste, directHunza0.2250.1330MAS-13533
139Ficus carica L.Faag, FaakFruit, stem latex (N, H, K), fruit (Gh)Poultice, direct, powder, pasteGhizer, Hunza, Jalalabad, Nagar0.2750.09687516203MAS-070, MAS-158, MAS-224, MAS-3559, 15, 16, 33
140Morus alba L.Marooch, Shae MaroochWhole plantDecoction, paste, directHunza, Jalalabad0.2750.0657637119MAS-171, MAS-2309, 15, 32, 33
141NitrariaceaePeganum harmala L.Spandur, Isman, Ispandure, SupandourWhole plant (N, H), seed (Gh, S)Powder, decoction, paste (H)Ghizer, Gojal, Hunza, Nagar, Skardu0.2883330.09772814143MAS-063, MAS-120, MAS-352, MAS-4569, 16, 17, 33, 38, 53
142NyctaginaceaeMirabilis jalapa L.Gul-e-AbbasFlowerPasteHunza, Kargha0.18750.142857214MAS-176, MAS-30240, 41
143OleaceaFraxinus hookeri Wenz.KasunarBark, woodDecoctionJalalabad0.2750.047619242MAS-19515
144Fraxinus xanthoxyloides (G.Don) Wall. ex A.DC.KasunarBark, woodDecoctionJalalabad0.1750.055556236MAS-19615
145Olea ferruginea Wall. ex Aitch.KawooLeaf, wood, barkDirect, decoctionJalalabad0.20.071429114MAS-20015
146OnagraceaeEpilobium latifolium L.PondolLeaf, flowerPaste, decoctionSkardu0.2333330.071429114MAS-39012
147OrchidaceaeDactylorhiza hatagirea (D.Don) SoóNarmadaRoot, rhizomePowderGojal0.150.090909111MAS-09417
148OrobanchaceaePedicularis cheilanthifolia SchrenkSerfo spanthingLeafDecoctionSkardu0.30.166667212MAS-39612
149Pedicularis pectinatiformis BonatiSunpo spanthingLeafInfusionSkardu0.2333330.157895319MAS-39712
150PapaveraceaeCorydalis crassifolia RoyleSackros/ZarvoshWhole plantGojal0.20.14285717MAS-09317
151Papaver somniferum L.MardakhawLatexDecoctionHunza0.1750.115385326MAS-1369, 33
152PinaceaePinus roxburghii Sarg.ChirpineResin, woodPaste, powder, directGhizer0.2333330.121212433MAS-04737
153Picea smithiana (Wall.) Boiss.KachulResin, woodPowder, decoctionJalalabad0.20.071429114MAS-20115
154Pinus gerardiana Wall.ex Lamb.CheenhResin, wood, leafDecoction, direct, paste, powder (k)Jalalabad0.1750.096774331MAS-20215
155Pinus wallichiana A.B.Jacks.CheenhResin, wood, leafInfusion, powderNagar0.1750.142857321MAS-34015
156PlantaginaceaePlantago ovata Forssk.IspagholSeed, leaf, rootPowder, infusionGhizer0.2333330.069767343MAS-04816
157Picrorhiza kurroa Royle ex Benth.KarrooLeaf, bark, root, rhizomePasteKargha0.20.130435323MAS-24411
158Plantago major L.Shiltive, BoqnaRoot, seed, leaf (K), seed (S), leaf, seed (Gh, H)Direct, decoction, oil (S)Ghizer, Hunza, Kargha, Skardu0.28750.1044829127MAS-073, MAS-161, MAS-282, MAS-4669, 14, 33, 37, 38, 53
159Plantago lanceolata L.Sman Hrswa, Sepgilk, YeepsFlower, leaf (S), leaf, seed (H)Decoction, infusion, paste (S), ash (H)Gojal, Skardu0.2958330.121667649MAS-131, MAS-48512, 17
160PoaceaeZea mays L.MakayeeFruitDirectHunza0.1250.14285717MAS-1399, 33
161Cymbopogon jwarancusa (Jones) Schult.Izkhar MakkiFlowerDecoctionKargha0.1750.133333215MAS-24240, 41
162Pennisetum glaucum (L.) R.Br.Cha soqStemDirectKargha0.1750.0625116MAS-24339
163Saccharum bengalense Retz.PhorooRoot, stemPowderKargha0.1750.190476421MAS-24714
164Hordeum vulgare L.Cha Fay, YorkSeedPowderGojal, Kargha, Skardu0.2638890.161905424MAS-129, MAS-299, MAS-48317, 39
165Avena sativa L.Nas Choo, ShesharSeed (S), seed, leaf (H)DecoctionHunza, Skardu0.2708330.144796547MAS-190, MAS-4969, 39
166PolygonaceaeRheum tibeticum Maxim. ex Hook. f.SheepodStemDirectGojal0.20.14285717MAS-10217
167Bistorta amplexicaulis (D.Don) GreeneOnbuRootPowder, decoction, infusionSkardu0.2666670.214286314MAS-38712
168Polygonum affine D. Don.Strin mindoqRoot, flowerDecoction, infusionSkardu0.40.142857321MAS-39812
169Polygonum tataricum L.Bro Kho-BroLeaf, seedPowder, decoctionSkardu0.2333330.157895319MAS-39938
170Rheum spiciforme RoyleKhakholLeaf, rootDirect, powderSkardu0.2666670.214286314MAS-40539
171Rumex chalepensis Mill.Sa-shingRootDecoctionSkardu0.2666670.083333112MAS-40838
172Fagopyrum esculentum MoenchBro, Ghiawas, Stabro, BarawSeed (K, H, A), leaf, seed (S)Direct, paste, powderAstore, Hunza, Kargha, Skardu0.1958330.1509851289MAS-016, MAS-146, MAS-259, MAS-4289, 13, 33, 38
173Rumex nepalensis Spreng.Churkeen, RashonaRoot (K), leaf (A)PasteAstore, Kargha0.2291670.142857214MAS-021, MAS-263, MAS-43313, 14
174Rheum australe D. DonShoot, LachuRoot (K, A), leaf, root, stem (S)Powder, infusion, decoctionAstore, Kargha, Skardu0.2805560.155556850MAS-030, MAS-272, MAS-44212, 13
175Oxyria digyna (L.) HillSpan Harswa, SkyurbutaqLeaf (S), aerial (A)Powder, decoctionAstore, Skardu0.2333330.177778424MAS-036, MAS-44812, 38
176 Rheum emodi Jarochuntal, ChontalWhole plantDecoctionGhizer, Hunza0.2583330.120909561MAS-068, MAS-156, MAS-4619, 16
177Rumex hastatus D. DonChurkiWhole plant (K), leaf, root, stem, fruit (Gh)Direct, decoction, powder (Gh)Ghizer, Kargha0.30.093168353MAS-080, MAS-28614, 16, 37
178Bistorta affinis (D.Don) GreeneBumaLeafPowderKargha, Skardu0.2041670.142857214MAS-322, MAS-50739
179Polygonum hydropiper L.ThangmarcyLeaf (K), aerial (S)DecoctionKargha, Skardu0.26250.188235527MAS-333, MAS-51814, 38
180PrimulaceaePrimula macrophylla D. DonBenufshaWhole plantDecoction, powderGojal0.1750.083333112MAS-10117
181Primula denticulata Sm.DaooLeaf, rootDecoction, powder, infusion (s)Skardu0.40.2420MAS-40112
182Primula farinose L.SpangpunarFlowerPaste, decoctionSkardu0.3666670.142857214MAS-40238
183RananculaceaeClematis baltistanica Qureshi & ChaudhriMargush, Murgushi, ChindrikLeaf, flower (H), whole plant (K)PasteGojal, Jalalabad, Kargha0.2083330.086652676MAS-127, MAS-228, MAS-2989, 14
184Aconitum nepellus L.Booma, Sai boomaFlower, leaf (N, H, K), whole plant (K), aerial (S)DirectKargha, Nagar, Skardu0.20.231481731MAS-316, MAS-378, MAS-50111, 38, 53
185Ranunculus trichophyllus Chaix ex Vill.Threadleaf crowfootWhole plantPaste, infusionKargha0.1750.111111218MAS-24614
186Thalictrum foetidum L.MomeranLeafDirectKargha0.2250.14285717MAS-24839
187Aconitum violaceum Jacquem. Ex. StapfBoomaRootDecoction, powderSkardu0.2333330.25416MAS-37912
188Aquilegia fragrans Benth.Karfo Koo-kukLeaf, flowerPaste, decoctionSkardu0.2333330.133333215MAS-38238
189Aquilegia pubiflora Wall. Ex RoyleKoo-kukLeaf, flowerPasteSkardu0.2333330.111111218MAS-38338, 53
190Thalictrum foliolosum DC.MomyrunRootDecoctionSkardu0.40.142857214MAS-41238
191Delphinium brunonianum RoyleMakhotingLeaf, flower (K), whole plant (S, A)Decoction, powder (S), infusion (S)Astore, Kargha, Skardu0.2694440.132937875MAS-026, MAS-268, MAS-43812, 13, 38, 39
192Pulsatilla wallichiana (Royle) Ulbr.Zgiongmonana LoqparimandoqFlowerPowderAstore, Skardu0.3166670.142857214MAS-038, MAS-45013
193RosaceaeComarum salesovianum (Stephan) Asch. & Graebn.Noghurdoom wooshFlowerGojal0.1750.14285717MAS-0929
194Potentilla eriocarpa Wall. ex Lehm.AmberLeaf, flowerGojal0.10.14285717MAS-09917
195Potentilla microphylla D. DonZatspirgLeaf, seedGojal0.1750.22222229MAS-10017
196Rubus irritans FockeIcheejehFruitDirectJalalabad0.3250.061224349MAS-20715
197Potentilla argyrophylla Wall. ex Lehm.Serfo HarswaWhole plantPasteSkardu0.4666670.14285717MAS-40012
198Rosa webbiana Wall. ex RoyleShighaye, Sia marpho, Chereer, Sia sarfoBark, wood (K), flower, bark (S), fruit, seed, wood (H, A)DecoctionAstore, Gojal, Hunza, Jalalabad, Skardu0.2383330.10398910116MAS-010, MAS-110, MAS-144, MAS-4229, 13, 15, 17, 38, 53
199Prunus armeniaca L.Jui, Jaroty, ChooliFruit, kernel, oilDirect, oil, powder, pasteAstore, Hunza, Jalalabad, Kargha, Nagar, Skardu0.2763890.08258649706MAS-015, MAS-145, MAS-218, MAS-4279, 13, 15, 32, 33, 38, 39
200Spiraea canescens D.DonDarah, SkhsiFlower, stem, woodOil, decoctionAstore, Jalalabad0.1750.066667352MAS-018, MAS-21913, 15
201Potentilla salesoviana Steph.Sniarmastwa, Karfo mindoqFlowerInfusion (s), pasteAstore, Kargha, Skardu0.2222220.116883878MAS-029, MAS-271, MAS-44112, 13,38
202Rosa brunonii Lindl.SiaMarpho, SiyaBarkDecoction, powder (k), infusion (s)Astore, Kargha, Skardu0.2166670.142857321MAS-031, MAS-273, MAS-44312, 13
203Prunus dulcis (Mill.) D.A.WebbBadum, Balth, Kono, Stargi marKernel, flowerDirect, oil, paste, decoction (s)Ghizer, Hunza, Jalalabad, Kargha, Nagar, Skardu0.2319440.1189321194MAS-069, MAS-223, MAS-354, MAS-46215, 16, 32, 39
204Rosa indica L.GhulabFlowerPaste, oilGhizer, Hunza, Skardu0.3138890.090149662MAS-076, MAS-164, MAS-46932, 37, 38
205Malus domestica Borkh.SkamkooshuFruitPowderKargha, Skardu0.2708330.142857214MAS-332, MAS-51739
206Potentilla bifurca L.TarqanFlower (K), aerial (S)Infusion (S), decoction (K)Kargha, Skardu0.3458330.103343454MAS-334, MAS-51912, 38, 39
207Prunus persica (L.) BatschTakushu ChooFruitPaste (k), decoction (s)Kargha, Skardu0.23750.171429317MAS-335, MAS-52039, 53
208SalicaceaeSalix babylonica L.MuchoorLeaf, bark, seed, gumDecoction, paste, directHunza0.1250.142857428MAS-1389
209Salix acmophylla Boiss.BrawoonLeaf, bark, stem, branchesDecoction, pasteJalalabad0.2750.074627567MAS-20815, 53
210Salix denticulata AnderssonBrawoonLeaf, bark, stem, branchesDecoction, paste, directJalalabad0.2250.083333560MAS-20915
211Salix iliensis RegelBrawoonLeaf, bark, stem, branchesDecoction, paste, directJalalabad0.1750.09434553MAS-21015
212Salix sericocarpa AnderssonBrawoonLeaf, bark, stem, branchesDecoction, paste, directJalalabad0.1750.096154552MAS-21115
213Salix turanica NasarovBrawoonLeaf, bark, stem, branchesDecoction, paste, directJalalabad0.20.1550MAS-21215
214Salix alba L.Mori Bayao, BayoLeaf, barkDecoction, paste, directGhizer, Kargha0.2250.099462555MAS-081, MAS-28714, 16
215Populus alba L.Fulsoo, TuraqLeaf, wood (K), leaf (H)DecoctionHunza, Jalalabad0.13750.107143221MAS-172, MAS-2319, 15, 33
216Populus nigra L.JerpaLeafDecoctionHunza, Jalalabad, Nagar0.1666670.119048328MAS-175, MAS-234, MAS-36315, 33
217Salix tetrasperma Roxb.Byao, BewLeaf, barkDecoction, paste, directHunza, Kargha0.20.107143221MAS-177, MAS-3039, 14
218SaxifragaceaeSaxifraga hirculus L.SitbarkWhole plantDecoctionGojal0.150.117647434MAS-10317
219Bergenia himalacia Boriss.SanspurRootPowder, decoctionKargha0.1750.133333215MAS-2419, 11, 12, 16, 33, 53
220Bergenia stracheyi (Hook.f. & Thomson) Engl.Sasper, KhichlayRoot, leafInfusion, powder, paste, directGhizer, Hunza, Nagar, Skardu0.256250.1494418124MAS-075, MAS-163, MAS-357, MAS-4689, 11, 12, 16, 33
221Bergenia ciliata (Haw.) Sternb.Shafus, ShaphusLeaf (K), leaf, seed (S)Powder, decoction, directKargha, Skardu0.3083330.1623381275MAS-321, MAS-50612, 13, 39
222SolanaceaeSolanum nigrum L.Gabeeli, Gabilo, DrumbashokhloWhole plant (N,Gh), leaf, fruit (K), fruit, seed (H), fruit (A)Direct, decoction (K), powder (Gh)Astore, Ghizer, Gojal, Kargha, Nagar0.2433330.12542620190MAS-005, MAS-053, MAS-252, MAS-34313, 14, 16, 17, 37
223Hyoscyamus niger L.LandungstwaSeedPaste, poultice, decoctionAstore, Kargha, Skardu0.250.15873319MAS-027, MAS-269, MAS-43913, 53
224Datura stramonium L.Daturo, DaturaSeed (H), flower, fruit, seed, leaf (Gh, K)Decoction, ash (K), paste (K)Ghizer, Hunza, Kargha0.2666670.10528613138MAS-071, MAS-159, MAS-2809, 14, 16, 33, 37, 53
225Capsicum annuum L.MaroochFruitDirectHunza, Nagar0.23750.0656135101MAS-187, MAS-3709
226TamaricaceaeMyricaria squamosa Desv.TargLeaf, flowerPowderGojal0.1750.178571528MAS-09717
227ThymelaeaceaeDaphne mucronata RoyleNirkoLeaf, fruit, woodPaste, poulticeJalalabad0.2750.088889445MAS-19315
228UrticaceaeUrtica dioica L.KhaeshingWhole plant (S, K), leaf, root (Gh)Direct, decoction, paste (S)Ghizer, Kargha, Skardu0.2361110.13267512149MAS-087, MAS-293, MAS-47513, 37, 53
229ViolaceaeViola serpens Wall. ex Ging.Skora mindoq, LilloFlower (S), whole plant (Gh, H)DecoctionGhizer, Hunza, Skardu0.2583330.124008658MAS-077, MAS-165, MAS-4709, 16, 33, 38
230ZingiberacaceaeCurcuma longa L.HalichiStemPowderHunza, Nagar0.2750.088933445MAS-188, MAS-37132
231ZygophyllaceaeTribulus terrestris L.Kokoloq, Kokoring, Huk ga kuriceWhole plant (Gh, K, A), seed (S), fruit (H)Paste, decoctionAstore, Ghizer, Hunza, Kargha, Skardu0.230.142857963MAS-008, MAS-056, MAS-255, MAS-4209, 13, 33, 37, 38, 39
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Details of the age and gender of participants of survey

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Age groups of participants, and the average number of species reported from different age group and retailers

During the survey, the participants revealed that medicinal plants are acquired from special locations and at a specific time, i.e., during a FGD in Upper Hunza (Gojal), the participants mentioned that medicinal plants are found both at the village and in pastures, yet the plants from pastures are used for medicinal purposes as those found in villages are not considered effective for medication. This needs to be scientifically verified from the field area, yet cases of same plant species presenting different chemical traits has been a known fact [94, 95].

Occurrence and markets for medicinal plants in Gilgit-Baltistan

Interpolated results revealed that the utilization as well as high occurrence of medicinal plants is mainly concentrated in two locations (Fig. 7). Valleys from Skardu, Gilgit, and Ghizer are reported for the highest number of medicinal plants and their uses. There are no formal markets for medicinal plants in the region [35]. Gilgit and Skardu being the main business hubs serve as main markets for wholesale, retail, and purchase of medicinal plants. Besides, small amounts of the medicinal plants are supplied to bigger markets in Rawalpindi and Lahore by the wholesalers. The market players reported Skardu, Astore, and Gilgit districts as the main suppliers of medicinal plants as well.

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Habitat/life form of species reported during the survey

Participants from the market revealed that most of the large herbal medicine production companies in Pakistan rely on raw materials from Indian Territory representing the same region across the border. Although a clear percentage of product flow was not known, during the market survey, the participants mentioned that the current markets for locally available plants are limited to the small town market centers and partly target markets in big cities like Rawalpindi (10%) and Lahore (10%) with meager shares moving out across the border to China (1–2%). The participants emphasized the involvement of government agencies for sustainable promotion, collection, and utilization of diverse plant resources in the region.

According to the retailers in Gilgit-Baltistan, Thymus linearis, Delphinium brunonianum, Bergenia stracheyi, Saussurea heteromalla, Saussurea lappa, Carthamus tinctorius, Peganum harmala, Rheum emodi, Mentha longifolia, Mentha arvensis, Valeriana wallichii, Berberis lyceum, and Elaeagnus rhamnoides account for the most demanded and utilized species. Although most of the customers were aware of the uses, the retailers had significant knowledge of the plant species they sold. Our survey results revealed that there is a large group of locals in Gilgit-Baltistan who rely on traditional medicine, yet these practices and the knowledge associated with them is rapidly depleting from the region. All the participants included in the survey had used medicinal plants for treating a medical condition at least once in their life. 79.5% of participants reported a transfer of knowledge from family elders. Out of these, 48% were above 50 years, 38% above 40 years while only 13% were below 40 years of age. 29.1% reported learning from community elders, of whom 64% were above 50 years, 32% above 40 years and only 3% below 40 years. 15.6% reported that they had acquired knowledge through interaction with other people, including THPs, plant collectors, and traders from other communities that include 87% above 50 years and 13% above 40 years. 20.1% were not aware of any treatments through medicinal plants which included only 4 and 26% participants above 50 and 40 years of age respectively while 70% of these participants fell below 40 years of age. Our results clearly indicate that the main source of knowledge transfer rests within the family. Yet only 13% of participants below the age of 40 confirmed that they had received such knowledge from within the family. Traditional healers in the community are experts in recognizing and collecting medicinal plants while other community members are not fully aware of the exact timing for collection. This is one of the main reasons why knowledge transfer is mainly through family elders as family secrets are not shared with outsiders. This allows the family to practice special medicinal remedies as well as retain a good image as regular suppliers to the wholesalers, retailers, and THPs in the region. The gradual expansion of trade and an increasing demand for medicinal plants in and outside the region has a positive impact on knowledge sharing. Most of the suppliers involved in the supply chain of medicinal plants represent the age group 40–60 which raises great concern for the future. Those representing the younger age group are either not collecting proper plants at the proper time or are too keen on gaining more financial benefits, thus not taking long-term conservation into account while collecting. This ever increasing gap between the young and old generation is affecting the knowledge transfer mechanism, in combination with over-exploitation and lack of conservation strategies, and the impacts of climatic changes. Such issues have also been observed in other studies [9, 30, 34, 42].

Informant consensus factor (ICF)

The ICF analysis was done separately for each location in order to assess a clearer picture on which diseases stand out at each location and how many plant species are utilized for their treatment. Table 1 includes the ICF values for diseases divided into 29 disease categories from each of the study locations. The table indicates that stomach and intestinal disorders, respiratory disorders, skin infections, internal and external wounds, pain relief, ear, nose and throat disorders, hepatitis, and livestock diseases were the top disease categories reported from all the field sites during the field study. Most of the ailment categories were reported with a high ICF value based on the number of species and their usage reports. This is an indication of homogeneity in responses of the participants from each of the study sites in terms of the medicinal plant species and the modes of their use for addressing a particular disease. The results from ICF values clearly indicate that diseases related to stomach and intestinal disorders; respiratory disorders especially asthma; skin infections; and ear, nose, and throat infections were most common diseases, which is also supported by various publications [13, 18, 41]. Besides, the communities generally rely on medicinal plants for treating different kinds of internal and external wounds [10, 13, 18, 39, 41]. It is also evident that community members owning livestock hugely depend on traditional mode of medication [38].

Table 1

ICF, number of uses, and species used for each disease category

Category of diseasesCentral HunzaGhizerGojal HunzaJalalabadKarghaNagarSkarduAstore
ICFNumber of use reports% age of use reportNumber of species used% age of speciesICFNumber of use reports% age of use reportNumber of species used% age of speciesICFNumber of use reports% age of use reportNumber of species used% age of speciesICFNumber of use reports% age of use reportNumber of species used% age of speciesICFNumber of use reports% age of use reportNumber of species used% age of speciesICFNumber of use reports% age of use reportNumber of species used% age of speciesICFNumber of use reports% age of use reportNumber of species used% age of speciesICFNumber of use reports% age of use reportNumber of species used% age of species
Wounds0.921034.8295.770.931014.1283.850.89486.1665.770.94973.9774.240.891859.36218.710.911397.18137.390.872099.04289.270.89193.8534.23
Skin infections0.921637.62148.970.932309.38167.690.89364.6254.810.9525610.49159.090.911386.98135.390.901487.64158.520.902229.60247.950.89459.1368.45
Pain relief0.9534015.901710.900.922279.25188.650.92496.2954.810.9429011.881710.300.9019910.07208.300.9321411.05158.520.892038.78237.620.91234.6734.23
Kidney and uterus0.951014.7263.850.90994.04115.290.94192.4421.920.961225.0063.640.861105.56166.640.951186.1073.980.851375.92216.950.89387.7157.04
Diaphoretic0.0000.0000.001.0070.2910.480.0000.0000.000.0000.0000.001.0030.1510.410.0000.0000.000.0000.0000.000.0000.0000.00
Others0.95823.8353.210.931415.75115.290.88708.9998.650.91361.4742.420.89201.0131.240.931105.68105.680.0000.0000.000.0000.0000.00
Cardiac stimulant1.00110.5110.640.91361.4741.920.85141.8032.880.94913.7363.640.85140.7131.240.95201.0321.140.89100.4320.660.0000.0000.00
Stomach and intestine0.9430514.261811.540.9342917.493014.420.9012616.171413.460.962369.67116.670.9048324.435121.160.9127114.002413.640.9063827.586320.860.8710721.701521.13
Asthma/breathing/respiratory/pulmonary0.931808.42148.970.9426110.64178.170.908010.2798.650.941345.4995.450.901457.33156.220.931226.3095.110.862109.08309.930.906813.79811.27
Anti-inflammatory0.92140.6521.280.90622.5373.370.92141.8021.920.91652.6674.240.84512.5893.730.90412.1252.840.83421.8282.650.0000.0000.00
Cancers1.0080.3710.640.93441.7941.920.0000.0000.001.00672.7410.610.93412.0741.660.0000.0000.000.0000.0000.001.0051.0111.41
Cytoprotective0.92502.3453.210.941245.0683.850.8891.1621.920.941225.0084.850.92663.3462.490.92402.0752.840.89200.8630.991.0051.0111.41
HIV0.0000.0000.000.0000.0000.000.0000.0000.000.0000.0000.000.0010.0510.410.0000.0000.000.0000.0000.000.0000.0000.00
Hepatitis0.90944.39106.410.90502.0462.880.85344.3665.770.92662.7063.640.78381.9293.730.92653.3663.410.85492.1282.650.85418.3279.86
Anti-stress/hypertension0.93703.2763.850.93421.7141.920.85141.8032.880.95391.6031.820.87160.8131.240.92402.0742.270.88331.4351.661.00142.8411.41
Hepatoprotective/liver0.94190.8921.280.92271.1031.440.0000.0000.000.91833.4084.850.86231.1641.660.96241.2421.140.81281.2161.991.0040.8111.41
Ear, nose, and throat0.942119.86148.970.931777.22146.730.9010112.971211.540.9426610.901710.300.871437.23197.880.951698.73105.680.841396.01247.950.86438.7279.86
Menses/diseases0.90432.0153.210.88170.6931.441.0050.6410.960.93311.2731.820.90110.5620.830.90502.5863.410.90110.4820.661.0051.0111.41
Brain and nervous disorders1.00100.4710.640.89281.1441.920.0000.0000.000.931285.24106.061.0050.2510.410.81170.8842.270.8680.3520.660.0000.0000.00
Weight loss and fat reduction0.96261.2221.280.86230.9441.920.90111.4121.920.0000.0000.001.0070.3510.410.91452.3252.840.89200.8630.990.0000.0000.00
Eye diseases0.96261.2221.280.93150.6120.960.88172.1832.880.93281.1531.820.93150.7620.830.94170.8821.140.83251.0851.660.0000.0000.00
Diabetes0.97321.5021.280.90622.5373.371.0050.6410.960.92391.6042.420.87160.8131.240.90643.3173.980.82291.2561.990.0000.0000.00
Teeth and gums0.92391.8242.560.91351.4341.920.0000.0000.000.93451.8442.420.85211.0641.660.92261.3431.700.88411.7761.990.88265.2745.63
Blood purifier/diseases0.93843.9374.490.911315.34136.250.91232.9532.880.951114.5574.240.86643.24104.150.93693.5663.410.871255.40175.630.87316.2957.04
Vomiting/nausea/altitude sickness0.0000.0000.000.0000.0000.001.0030.3910.960.0000.0000.000.0000.0000.001.0070.3610.571.0070.3010.331.0071.4211.41
Livestock diseases0.96944.3953.210.92612.4962.880.87769.761110.580.93441.8042.420.891326.68156.220.88753.87105.680.871024.41144.640.91122.4322.82
Sexual diseases/stimulant1.0090.4210.640.94170.6920.960.94192.4421.920.94190.7821.211.0050.2510.411.0040.2110.570.0000.0000.000.0000.0000.00
Hemorrhoids/piles1.0070.3310.641.0070.2910.481.0030.3910.960.92140.5721.210.88251.2641.660.94331.7031.701.0050.2210.330.0000.0000.00
Maternal health0.94180.8421.280.0000.0000.001.0030.3910.961.00120.4910.610.0000.0000.001.0080.4110.570.0000.0000.000.0000.0000.00

Relative frequency of citation (RFC) and use value (UV)

The RFC and UV values for each plant species were calculated in order to validate the frequency of citation for the species used for different ailment categories. The values were calculated at district level in order to authenticate the local frequency of use. The RFC value is used for verifying the use of a medicinal plant species for different diseases while the UV value is an indication for the relative importance of these species in a particular population [78]. The highest RFC value from all the sites was calculated for Dracocephalum nuristanicum Rech.f. & Edelb. (0.7) followed by Cupressus sempervirens L., Prunella vulgaris L., and Potentilla argyrophylla Wall. ex Lehm., averaged at 0.47 each indicating that these species were highly reported by the participants of the study. RFC directly depends on the number of participants mentioning use of a particular plant (FC); therefore, the abovementioned plants were very commonly used in the study area. The UV values for Amaranthus viridis L. (0.33), Artemisia herba-alba Asso (0.28) and Astragalus zanskarensis Bunge (0.25), and Aconitum violaceum Jacquem. Ex. Stapf (0.25) were the highest averaged from the field sites. The results indicate the usage and reliance on medicinal plants for treatment of multiple diseases. Such reliance on medicinal plants in both humans and livestock are reported from the region [9, 16, 18, 30, 34, 38, 41]. Table 2 includes a list of reported species from all the six districts of Gilgit-Baltistan with their local names, parts used, mode of their utilization, the average values for RFC and UV, number of ailment categories addressed, and the number of uses reported for each of the plant species. Area wise details for each of these species is provided in Additional files 2, 3, 4, 5, 6, 7, 8, and 9 while the detailed list of diseases categorized in 29 ailment categories is provided in S12.

Medicinal systems and affiliations

This region has already witnessed invasion by different cultures and practices [3, 4651]. The passes created by the Indus River system in Hunza, Shigar, Shyjok, Ghizer, Gilgit, and Astore valleys served as the main travel routes for such invasions and exchanges as Gilgit got its famous name “gate to India” [3]. This region witnessed influence from Chinese, Tibetan, ancient Indian, and Unani systems [3, 46]. This influence was reflected during the field survey while recording the uses and modes of use of medicinal plants.

Fifty percent of the participants were able to answer the question related to influence of medicinal systems on the indigenous knowledge existing in the region; where 28% referred to Chinese influence, 23% chose Indian subcontinent while 18 and 14% selected Scythian/Transoxianan, and ancient Greek influence on the traditional medicinal system. It is worth mentioning that 41% of these participants referred to a mix of at least two of these systems in the current traditional medicinal system. Most of the participants from Astore and Skardu mentioned Indian subcontinent followed by Scythian/Transoxianan and ancient Greek influence while participants from Hunza, Nagar, Gilgit, and Ghizer ranked Chinese influence on top followed by Indian subcontinent, Scythian/Transoxianan, and ancient Greek. The market players on the other hand opted for a mix of all these systems together as they deal with customers from the whole region and are exposed to all medicinal systems prevailing in the region. Another reason for a mixed system described by the market players is the fact that these markets were traditionally placed at regional centers, thus were exposed to THPs representing different systems. Their experiences with these THPs and fulfilling their demands made them acquire traits from all the systems. Although a clear boundary could not be drawn between these systems, it is likely that medicinal practices in Hunza, Nagar, Ghizer, and Gilgit were influenced by traditional Chinese medicine (TCM) system while the remaining part of study area was dominated by a mix of Ayurveda and Unani systems.

Discriminant analysis (DA)

Discriminant analysis revealed that Astore was distinct from other surveyed areas whereas some overlap can be observed in other surveyed areas (Fig. 8). Gojal showed similarity with Skardu and Kargha, while Jalalabad showed few similarities with Kargha and Hunza. Hunza, Nagar, and Ghizer showed very similar traits while sharing few similarities with Skardu, Kargha, and Jalalabad. This analysis mainly considered top 10 medicinal plants used and the parameters calculated from each location. This does not represent linkage with healing systems but separates geographical location, tribal representation, and connectivity to other parts of the region, e.g., China, India, and routes to Western Asia. It also reflects on migration and integration of the local tribes as well as those coming from outside and provides an insight on the influence of different invaders, travelers, and businessmen.

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Percentage of the parts of plants used for medicinal purposes

Plant species have responded to latitudinal and elevational changes in their habitat and adjusted over time, yet the increasingly rapid pace of these changes is challenging their adaptability and ability to respond [9698]. The association of traditional knowledge with these species, trade potentials, and transfer of knowledge from old to new generation will have a direct effect on the conservation of plant species and associated TK [90, 99103].

Key discussion points

The environment and climatic conditions of Gilgit-Baltistan make it geographically one of the best locations for growth and nourishment of medicinal plants [6, 9, 34, 104]. Traditional medicinal practices hold a significant place in the lives of the local communities. The markets at Gilgit and Skardu are serving as trade centers for medicinal plants from the whole region, and the wholesalers stationed here are responsible for small-scale trade in important plant species in both local and national markets. The study shows that most of the large herbal medicine production companies in Pakistan rely on supply of medicinal plants from Indian territory—representing the same region across the border—indicating that the production and trade of medicinal plants is well organized across the border. The trade of medicinal plants in Pakistan is informal, with little to none state interventions and incentives [35, 105]. The high marketability of medicinal plants has led many local people to over-exploit this valuable resource. Over-exploitation of medicinal plant species is widespread across the region, exacerbated by some local people attempting to maximize financial benefits in a single harvest, with little concern for the ramifications for subsequent years [9, 30, 34, 42].

This study clearly reveals the importance and contributions of the THPs and retailers as well as the transfer of knowledge within the families from elders to the younger generation for the retention of indigenous medicinal knowledge, where and when to acquire a particular species and the utilization of medicinal plants. The THPs preserved existing knowledge and showed a great deal of openness to knowledge sharing. They attributed the loss of knowledge between generations, not to any failure of their own to impart knowledge, but rather to a lack of learning aptitude in the younger generation [34, 106]. Retailers have adapted well to the demands of different ethnic and tribal groups. These factors point towards a high level of cooperation, collaboration, and openness to knowledge exchange amongst the ethnicities and tribes of Gilgit-Baltistan. Local public and private institutes can therefore play a vital role in clustering the knowledge and bridging the gaps by providing platforms for recording, sharing, and disseminating traditional knowledge.

We found that Gilgit-Baltistan’s position as a gateway between the Central and South Asia caused its exposure to a number of traditional medicinal systems including the Ayurveda, traditional Chinese medicine, Unani, and Tibetan—which highly influenced traditional medicine knowledge in this region [3, 46]. Our study design and timeline restricted us from further exploration of these historical details. Therefore, we were not able to explore the timeline and actual contributions of these systems to local knowledge. However, it appears likely that medicinal practices in Hunza, Nagar, Ghizer, and Gilgit were influenced by traditional Chinese medicine (TCM) system while the remaining part of the study area was dominated by a mix of Ayurveda and Unani systems. This is an interesting finding and deserves further research. Most parts of Pakistan are primarily relying on a mix of Unani and Ayurveda medicinal systems—a combination which is rarely found elsewhere [107]. A dedicated study exploring the approaches followed by these medicinal systems, their complementarities, and differences could lead to the generation of highly valuable scientific findings that could contribute to the communities relying on these systems globally.

With the involvement of multiple stakeholders (the relevant local government departments, herbal medicine-producing companies, THPs, and the interest of the national government), medicinal plants and associated traditional knowledge from Gilgit-Baltistan can make a substantial contribution to traditional health practices at a national level as well as contribute significantly to the national market and the livelihood resources of local communities. Proper licensing will allow the THPs to legally practice, document, and disseminate their knowledge. The concerned government departments can provide a platform for THPs from the region to get registered and licensed as hakims [39]. Our effort to involve school students in the collection of data is a way of exposing the younger generation to identification of their resources and developing their interest in traditional knowledge and why it is important to ensure its transfer to them from the older generation. Such a consortium will also prove beneficial for the production of medicinal plants on a commercial scale, their sustainable utilization, and organizing refreshers on different aspects associated with medicinal plant resources for the local THPs, retailers, and collectors in order to ensure an optimal and efficient utilization of the available resources.

These points are of utmost importance when it comes to the conservation and transfer of traditional medicinal knowledge to future generations. Worldwide, patients are increasingly opting for medications involving traditional techniques, herbal medicine, and meditation [108, 109]. Gilgit-Baltistan has natural medicinal resources, a vast indigenous knowledge bank, and most importantly one of the best mountainous landscapes for tourism and meditation. It is doubtless the best option to be considered for developing into a sanctuary through government interventions. Gilgit-Baltistan, considered to be home to the ideology of “SHANGRI LA” with its abundant natural resources, can provide a home to those who seek medication through centuries-old traditional knowledge, sacredly transferred from one generation to another.

Conclusions and recommendations

The diverse plant resources and the geographical importance of the region for trade and travel routes, historically made Gilgit-Baltistan a hotspot for cultural, religious, and traditional knowledge exchange. Being part of an ancient trade route, the resident communities adapted and upgraded their traditional healing systems through interactions with the Indian subcontinent, China, Scythia, Transoxiana, and Ancient Greece. This influence and amalgamation of Chinese, Ayurveda, Unani, and Tibetan medicinal systems is apparent in local traditional knowledge. Our study revealed that most of the local people still rely on indigenous healing practices. Higher knowledge and use of medicinal plants is retained in the areas that also serve as main trade centers in the region. The trade of medicinal plants in the region is the one key factor in retaining traditional knowledge on medicinal plant utilization. This continued reliance on medicinal plants shows the significance of these traditional practices. A thorough evaluation is needed by ethno-pharmacologists and other concerned institutions working for public health and hygiene, especially focusing on THPs, market actors and old folk from the region. For strategies to be devised for market exploration, raising awareness, and continuity of TK, involvement is required from Government institutions, research organizations, NGOs, donors, and the private sector.

Additional files

Additional file 1:(637K, xlsx)

Primary data on medicinal plants and their uses collected during the field survey. (XLSX 636 kb)

Additional file 2:(15K, xlsx)

RFC and UV of species reported from Central Hunza. (XLSX 14 kb)

Additional file 3:(14K, xlsx)

RFC and UV of species reported from Ghizer. (XLSX 14 kb)

Additional file 4:(14K, xlsx)

RFC and UV of species reported from Gojal Hunza. (XLSX 13 kb)

Additional file 5:(14K, xlsx)

RFC and UV of species reported from Jalalabad. (XLSX 13 kb)

Additional file 6:(17K, xlsx)

RFC and UV of species reported from Kargha. (XLSX 17 kb)

Additional file 7:(13K, xlsx)

RFC and UV of species reported from Nagar. (XLSX 13 kb)

Additional file 8:(19K, xlsx)

RFC and UV of species reported from Skardu. (XLSX 19 kb)

Additional file 9:(13K, xlsx)

RFC and UV of species reported from Astore. (XLSX 13 kb)

Additional file 10:(14K, xlsx)

Top 10 species from each location for number of uses, ailment categories, RFC, and UV. (XLSX 14 kb)

Additional file 11:(12K, xlsx)

List of publications from the region reporting on medicinal plants and their uses. (XLSX 12 kb)

Additional file 12:(15K, xlsx)

Ailment categories. (XLSX 14 kb)

Acknowledgements

We are thankful to the participants of the field survey for their cooperation and time. The Law Enforcement Agencies at Gilgit-Baltistan especially Captain Faisal Anwar, Captain Muhammad Awais Salim, and their entire team are thanked for their support and provision of services in times of need.

Funding

The study was conducted under the “Investigating and recalibrating traditional ecological calendars and climate change adaptation in the Himalaya region” funded by Bureau of International Cooperation Chinese Academy of Sciences, Grant No. 151853KYSB20160032. Additional support was provided by the National Natural Science Foundation of China, Grant No. 41661144001. Funds acquired from these sources were utilized for field visits, collecting, and analyzing data and interpretation of results.

Availability of data and materials

In addition to the data presented through tables and figures in the main text, all the data supporting the findings and results is available in the additional files provided with the manuscript.

Abbreviations

CPECChina-Pakistan Economic Corridor
DADiscriminant analysis
FCFrequency of citation
FGDFocused group discussion
HHHousehold
HKHHimalaya Karakoram Hindukush Mountain Range
ICFInformant consensus factor
KKHKarakoram Highway
MAPsMedicinal and aromatic plants
NGONon-Governmental Organization
RFCRelative frequency of citation
TCMTraditional Chinese medicine
THPTraditional health practitioner
TKTraditional knowledge
UVUse value

Authors’ contributions

MAS, SR, and JX conceptualized, planned, and designed the study. MAS and TK led the data collection team of SA, CK, AP, ZB, and SB. MAS and SR analyzed the data, wrote, and finalized the manuscript. RH and JX revised the paper. SR and JX supervised the first author during his doctoral research. All the authors have read and approved the final manuscript prior to submission.

Notes

Ethics approval and consent to participate

The study is based on field surveys, and no human or animal trials were involved or conducted. Formal consent was obtained from participants prior to data collection and publication. In addition, International Society of Ethnobiology (ISE) code of ethics http://www.ethnobiology.net were strictly followed while conducting the research.

Consent for publication

Formal consent was obtained from participants prior to data collection and publication.

Competing interests

The authors declare that they have no competing interests.

Publisher’s Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Contributor Information

Muhammad Asad Salim, moc.evil@milasdasa.

Sailesh Ranjitkar, moc.liamg@raktijnar.hselias.

Robbie Hart, gro.tobom@trah.eibbor.

Tika Khan, kp.ude.uik@nahk.akit.

Sajid Ali, moc.liamg@100dahsiladijas.

Chandni Kiran, moc.liamg@049narikindnahc.

Asma Parveen, moc.liamg@568neevrapamsa.

Zahra Batool, moc.liamg@49nooraharhaz.

Shanila Bano, moc.liamg@92namaalinahs.

Jianchu Xu, nc.ca.bik.liam@uxj.

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