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Review

Some European Gentiana Species Are Used Traditionally to Cure Wounds: Bioactivity and Conservation Issues

by
Ardalan Pasdaran
1,2,
Zheko Naychov
3,
Daniela Batovska
4,
Philip Kerr
5,
Adrien Favre
6,
Vladimir Dimitrov
7,
Ina Aneva
8,
Azadeh Hamedi
2 and
Ekaterina Kozuharova
9,*
1
Medicinal Plants Processing Research Center, Shiraz University of Medical Sciences, Shiraz 73, Iran
2
Department of Pharmacognosy, School of Pharmacy, Shiraz University of Medical Sciences, Shiraz 73, Iran
3
University Hospital Lozenets, Department of Surgery, Sofia University St. Kliment Ohridski, 1407 Sofia, Bulgaria
4
RLG-2016, Bul. “Asen Yordanov” 14, g.k. Druzhba 1, 1592 Sofia, Bulgaria
5
Charles Sturt University, Boorooma St Locked Bag 588, Wagga Wagga, NSW 2678, Australia
6
Regional Nature Park of the Trient Valley, La Place 24, 1922 Salvan, Switzerland
7
Institute of Organic Chemistry with Centre of Phytochemistry, Bulgarian Academy of Sciences, Acad. G. Bonchev Str. 9, 1113 Sofia, Bulgaria
8
Institute of Biodiversity and Ecosystem Research, Bulgarian Academy of Sciences, 1113 Sofia, Bulgaria
9
Department of Pharmacognosy, Faculty of Pharmacy, Medical University of Sofia, 1000 Sofia, Bulgaria
*
Author to whom correspondence should be addressed.
Diversity 2023, 15(3), 467; https://doi.org/10.3390/d15030467
Submission received: 24 January 2023 / Revised: 5 March 2023 / Accepted: 10 March 2023 / Published: 22 March 2023
(This article belongs to the Special Issue Ethnobotany, Medicinal Plants and Biodiversity Conservation)
Browse Figures
Versions Notes

Abstract

:
Wound care will always be among the main tasks in all surgical specialties. Several medicinal plants have proven efficacy to cure wounds. Ethnobotanical research and ethnopharmacological research have virtually endless potential to find new lead compounds. The aim of this research review is to assess the potential of some Gentiana species as sources of promising active compounds to support wound healing. Gentians are among the most popular medicinal plants used in many countries for a wide spectrum of health conditions. Traditionally, those used to cure wounds are Gentiana lutea, G. punctata, G. asclepiadea, G. cruciata, G. oliverii, G. septemphida, and G. gelida. Candidate compounds with skin regeneration and wound-healing potential isolated from gentians are isogentisin, isoorientin, mangiferin, lupeol, pinoresinol, syringaresinol, eustomoside, and sweroside. Based on the rich source of traditional knowledge on the properties of gentians to cure various skin and soft tissue complications; only very few modern pharmacological studies have been performed to test this potential. Our review demonstrates that this field deserves further investigation. Many gentians are declining in number and have high IUCN conservation status, and cultivation and micropropagation methods are the only solution for the development of new drugs based on gentian extracts.

1. Introduction

Regardless of how far medical advancement proceeds, wound care will always be among the main tasks in all surgical specialties. Even as we find noninvasive or minimally invasive approaches to replace major surgery, trauma continues to exist alongside the chronic wounds, such as arterial and venous leg ulcers, diabetic foot, and pressure ulcers. Acute wounds are categorized as open traumatic injuries, and the standard approach in coping with them is usually mechanical: hemostasis, necrectomy, disinfection, drainage, and closure by means of certain devices (such as stitches, staplers, etc.). They might be complicated with infection, usually treated with antibiotics and antiseptics.
Chronic wounds, also known as ulcers, are of considerable medical, social, and economic importance. Brownrigg et al. [1] and Richmond et al. [1,2] report that approximately 2.5–4.5 million people suffer from chronic wounds in the USA alone. On average, these wounds persist for 12–13 months and reoccur in up to 70% of the patients, which leads to disability and a significantly poorer quality of life [2,3]. The main pathophysiological factors making these wounds so challenging include uncontrollable inflammation, infection, formation of nonpermeable biofilms, and inability of the tissue to adequately respond to reparative stimuli [4,5,6,7,8]. Typical approaches to their treatment involve prolonged use of antiseptics and some specific topical agents, which aim to destabilize the biofilm and promote tissue growth (such as providing a favorable moist environment, application of proteolytic enzymes, etc.). Nonchemical options include vacuum suction, physiotherapy (UV light and cold plasma), and even use of maggot larva to clean the wound bed [9]. However, most of the approaches currently used to cure both acute and chronic wounds lack evidence for their efficacy [10,11]. Medicinal plants, such as Curcuma longa, Terminalia arjuna, Centella asiatica, Bidens pilosa, Aloe barbadensis, Rauwolfia serpentina, Symphitum officinale, Hypericum perforatum, and Plantago major, are well known for healing wounds. Around the world, some of them are used in registered medications [12,13,14,15,16,17,18]. The aim of this review research is to assess the potential of some Gentiana species as a source of promising active compounds to support wound healing.

2. Materials and Methods

We accessed Google Scholar, Web of Science, and PubMed to identify publications for the period 1960–2022 with the search string: “Gentiana + ethnobotany”, “Gentiana + wounds”, “Gentiana + secondary metabolites”, “iridoid(s)” “secoiridoid(s)”, “flavonoid(s)”, “alkaloid(s)”, “xanthone(s)”, “lignans”, etc. Following the PRISMA 2000 guidelines, the records were assessed for eligibility, and the inappropriate ones were excluded. In addition, the Latin version of the text of Dioscorides was checked for the application of “gentian” as well as some local ethnobotanical publications [19,20,21,22,23,24,25,26,27,28,29,30]. Additionally, distribution maps were built for five species found to have applications to cure wounds, together with their IUCN conservation status assessments.

3. Results and Discussion

3.1. Ethnobotany—Gentiana Species Used in Folk Medicine in General

The “Traditional medicinal uses” of Gentiana species are summarized in Table 1. In general, gentians appear to be popular medicinal plants throughout Europe, with some species being used in different regions for diverse conditions. For instance, G. cruciata is the plant with the highest number of phytotherapeutic uses in the region of Suva Planina in Southeastern Serbia [19]. It is also among the most popular medicinal plants in Bulgaria [20].
However, the relative importance of a given Gentiana species as a medicinal plant may vary across the continent. This is the case for G. lutea, a plant from which preparations are very well established in the formulation of suitable remedies (e.g., to prepare brandy, Table 1). Indeed, whereas G. lutea has a wide spectrum of traditional uses in the Pyrenees, in the Suva Planina mountains, the species use is restricted to far fewer health conditions [21]. In summary, the popular traditional applications of gentians in Europe are for loss of appetite, as a stomachic, for gastrointestinal disorders, and for gallbladder and liver diseases. The traditional utilization of G. lutea is reflected by its being listed in the European Pharmacopoeia 2016, 2020 (as plant substance Gentianae Radix: 1365, Gentian tincture: 1366, 1870) as well as being listed in the European Medicines Agency handbook (EMA) 2018. In the Himalayan region, gentians are used to cure jaundice (Table 1).
In practice, both G. lutea and G. punctata can be replaced by G. asclepiadea and G. cruciata, respectively [22,23,24]. Other species, such as G. pneumonanthe, are also used as traditional remedies [25]. G. lutea is also among the most often traditionally used plants in Serbia and the Pyrenees [26]. The most popular application of this plant is as an appetizer. Other uses include as an antipyretic, for sores and minor wound healing; for stomach ulcers, as hepatoprotective; as hypoglycemic; as antianemic; as an immune stimulant; as cardiotonic; and as an astringent [27]. G. cruciata is one of the most popular medicinal plants in traditional Bulgarian medicine, and it has a wide spectrum of uses (Table 1) [20].

3.2. Ethnobotany—Gentiana Species Used in Folk Medicine to Cure Wounds

According to Dioscorides, the gentian (not perfectly clear exactly which species) is “a wound remedy, cures deep ulcers and helps with eye inflammation” [28]. In addition to this, he mentions many other properties, such as an antidote against venomous bites probably as a pain killer (he lists hernia, falls from heights, and dolor laterum—literally “pain in the sides”—this might be kidney stone pain or intercostal neuralgia), liver ailments, gastritis, and convulsions and as an abortifacient and against certain skin conditions (probably a form of leprosy). He also describes an interesting method of extraction: the roots are bruised and steeped in water for five days, then boiled, strained, and finally reduced to a thick liquid with the consistency of honey. The final product is stored in ceramic jars for further use.
Gentians are used to cure wounds in traditional medicine practices mainly in the Middle East, Caucasian and Mediterranean regions especially Iran, Turkey, Georgia, Bulgaria, and Greece, and also in the Cantabrian Mountains (Table 1). More detailed information about the wound-healing application of gentians in Bulgaria (Table 1), where we find the uses in the records of the Materials for Bulgarian Botanical Dictionary [20]. This valuable collection of common names and ethnobotanical data, such as the plant’s application for remedial purposes and also their use in traditional spells and magical rituals, were recorded by teachers, university professors, naturalists, folklorists, and physicians during 19th and 20th centuries [20].
The gentian used as poultices to cure eczema, ulcers, boils, purulent wounds, burns, and hard-to-cure wounds in Bulgaria is G. cruciata, while G. lutea, G. punctata, and G. asclepiadea are listed as substitutes (Table 1). According to some traditional Iranian texts, such as Makhzan Al Advieh, drinking a water extract of gentian root alone, or combined with wine, pepper, and rue, was used in traditional Persian medicine for wound healing, soft tissue inflammation, and skin and soft tissue wounds and animal bite treatments [29]. The plaster of gentian root with vinegar is used in traditional Iranian medicine to cure infected wounds in addition to other applications, such as the treatment of urinary retention, menstrual, liver, and spleen dysfunctions and the detoxification of animal (scorpion and viper) poisons [30]. The Gentians, which these authors list, in relation to their activity are G. olivieri., G. gelida, and G. septemfida as well as Gentianella caucasica.
More than ten Gentiana species occur in the Anatolian and Iranian Plateaus among which are G. aquatica L., G. cruciata L., G. gelida M.Bieb., G. olivieri Griseb., G. verna subsp. oschtenica (Kusn.) Halda., G. prostrata Haenke., G. riparia Kar. & Kir. and G. septemfida Pall [31,32]. In addition, G. septemfida in Georgia is often used against hemorrhoids, while in Turkey, several other gentians in addition to this one are applied for this purpose [33] (Table 1). Gentians are not mentioned for any medicinal application by Watkins in her research on native British plants used in the 10th century by Anglo Saxons [34]. However, to cure chronic wounds, they used a topical preparation of Centaurium erythraea, in addition to its other applications for snakebite, eye pain, poor vision, ‘anyone dangerously ill’, and possibly a specific medical condition, such as fever or nerve spasms.
Table
Table 1. Application of Gentiana species in various traditional medicines and regions.
Table 1. Application of Gentiana species in various traditional medicines and regions.
RegionPart(s) UsedApplication Mode and IndicationsReferences
Gentiana spp.
Epirus, Greece--On wounds, digestive system ailments, anthelminthic[35]
Traditional Persian medicineRootWater extract to treat different skin and soft tissue wounds and animal bites
Widely recorded for hemorrhoids		[29]
G. lutea L.
Bukovina Central Eastern Carpathians Ukrainian partRootsTea, diabetes, stomach ache, potency problems, and gastric ulcers[36]
Infused in alcohol and good for the liver[37]
Bukovina Central Eastern Carpathians
Romanian part		RootsInfused in strong alcohol—beverage[37]
Peshkopia, Rraice, and Mokra (Eastern Albania).Aerial partsTea
Cardiotonic		[26]
Pirot District, SerbiaRootsCold water and strong alcohol (raki) macerates improving the immune system, against circulatory disorders, aphrodisiac, digestive, stomach ache and ulcers, gastrointestinal disorders, beneficial effects in gall and liver diseases, blood purification, heart diseases, anemia, and as a mild sedative “lincura”[38]
Suva Planina Mts. SerbiaRootsAbdominal pains, digestive, strengthening the immune system (lincura—‘gentian brandy’)[19]
Kosovo (only in Serbian villages)Aerial partsTea for blood[39]
Prokletije Mts. MontenegroRootLoss of appetite, as a stomachic, as well as a component in preparations showing beneficial effects in gall and liver diseases
loss of appetite, flatulence, and digestive ailments, for worms		[40]
North and northeast Bosnia and HerzegovinaRootAilments: loss of appetite, flatulence, and digestive ailments, for worms, influenza infection[41]
Friulians in northeast Italy and Slovenia, As ointments obtained from plant maceration in grappa[42]
Swiss Alps Recreational grappa [42]
Cantabrian Mountains SpainRootDecoction for purulent wounds[43]
G. lutea subsp. symphiandra (Murb.) Hayek
BulgariaRoot“Same application like G. cruciata, but it has stronger activity” (see below for Bulgaria) incl. wounds[20]
Pešter Plateau (southwestern Serbia) both Serbian and Albanian communitiesRootsTea or cold macerate in water—digestive troubles, stomach ache, diarrhea[27]
Northern Albanian AlpsRootMacerated in raki (strong alcohol) and taken to treat heart diseases[44]
Bosnia and Herzegovina
Dinaric Alps		RootStomach and heart disorders, recovery, macerate, decoction, tincture[45,46]
Aosta Valley, Western Alps, ItalyRootLiqueur and grappa as digestive root decoction against digestive and liver problems, as tonic and appetizer, root decoction in wine as invigorating and against anemia[47]
SpainRootsBoiled or soaked in wine or in a liqueur—digestive beverage[48]
North and northeast Bosnia and HerzegovinaRootAilments: loss of appetite, flatulence, and digestive ailments, for worms, cardiovascular system disorders[41]
G. punctata L.
BulgariaRoot“Identical application like G. lutea” (see above for Bulgaria) incl. wounds[20]
Pirot District, SerbiaRootsInfused in strong alcohol—beverage, loss of appetite, gastrointestinal disorders, beneficial effects in gall and liver diseases, anemia, improves digestion, against circulatory disorders, and as a mild sedative.[38]
Prokletije Mts. MontenegroRootsLoss of appetite, as a stomachic, as well as a component in preparations showing beneficial effects in gall and liver diseases[40]
Aosta Valley, Western Alps, ItalyRootLiqueur and grappa as digestive root decoction against digestive and liver problems, as tonic and appetizer, root decoction in wine as invigorating and against anemia[47]
G. asclepiadea L.
BulgariaRoot“Same application like G. cruciata” (see below for Bulgaria) incl. wounds[20]
Bukovina Central Eastern Carpathians
Romanian part		Aerial partsInfused in strong alcohol—beverage[37]
SerbiaRoot
“the underground parts yellow as wax”		Remedy against jaundice, after jaundice, digestive disorders, to improve appetite, against gall and liver diseases, against anemia, and for general strengthening of the immune system[38]
Prokletije Mts. MontenegroRootsLoss of appetite, as a stomachic, component in preparations showing beneficial effects in gall and liver diseases[40]
Bosnia and Herzegovina
Dinaric Alps		RootsInfusion, decoction, tincture for diseases of internal organs, especially liver and pancreas[45]
G. verna L.
Aosta Valley, Western Alps, ItalyFlowers (fresh or dried)Liqueur and grappa as digestive and appetizer, invigorating against headaches caused by cold and respiratory problems[47]
G. cruciata L.
BulgariaAerial partsDecoction, improves appetite, abdominal pain, gastrointestinal disorders, diarrhea, constipation, beneficial effects in gall and liver diseases, jaundice, anemia, blood purification, malaria, tuberculosis, gout, dysmenorrhea, amenorrhea, kidney sand stone and inflammation, bronchitis, improves lactation, calming on the CNS, against hysteria and hypochondria, vertigo, against worms, hemorrhoids, decoction or tincture for poultices to cure eczema, ulcers, boils, purulent wounds, burns, hard-to-cure wounds.[20]
Pirot District, SerbiaAerial partsCold water or strong homemade alcohol macerate—cancer, cold, and fever; improves the immune system, diabetes, inflammation, blood purification, high blood pressure, lung disease.[38]
Suva Planina Mts. SerbiaWhole plant in flowerWomen’s illnesses, cholesterol, diabetes, to improve digestion, liver and gallbladder complaints, stomach ailments (stomach ulcers), diseases related to the throat and esophagus, diseases of the chest, blood detoxification, improves appetite and immune system, antianemic (tea)[19]
Prokletije Mts. MontenegroRoots, aerial partsLoss of appetite, as a stomachic, as well as a component in preparations showing beneficial effects in gall and liver diseases[40]
Mountain Regions of Far Eastern Europe (Caucasus to Middle Urals)Whole plant,

eaves 		Infusion is used for epigastric pains, rabies, and plague, as antifebrile and anthelmintic, for wound healing, rheumatoid arthritis, gout, and early chlorosis and topically for purulent wounds;
used for liver, gallbladder, and stomach ailments		[49,50,51]
Transcaucasus Decoction is used for diseases of the stomach, malaria, hemorrhoids, infertility, and as hemostatic[49,50,51]
Middle Urals Infusion is used for headaches and as anthelmintic[49,50,51]
G. kochiana Perr. et Song.
Prokletije Mts. MontenegroRoots, aerial partsLoss of appetite, as a stomachic, as well as a component in preparations showing beneficial effects in gall and liver diseases[40]
G. acaulis L.
Aosta Valley, Western Alps, ItalyFlowers (fresh or dried)Liqueur and grappa as digestive and as appetizer, invigorating against headaches caused by cold and respiratory problems [47]
G. pneumonanthe L.
Deliblato Sands, Serbia RhizomeTea is used as a tonic, for strengthening the digestive organs and improving appetite[25]
G. septemfida Pall.
Mountain Regions of Far Eastern Europe Leaves

Roots		Cholagogue, for stomach pain and liver and gallbladder ailments
Water extract and the decoction are used to treat malaria and for stomach problems		[49,50,51]
Azerbaijan and GeorgiaRoots

Leaves 		Decoction is used to treat malaria and for stomach problems
Prepared as tea and used as cholagogue, for stomach pain and liver and gallbladder ailments		[23,52,53,54,55]
Georgia --Cardiovascular, etc.[33]
Turkey --Cardiovascular, hemorrhoids, etc.[33]
Iran RootPlaster with vinegar against bites of poisonous animals and to cure infected wounds, to treat urinary retention, menstrual, liver and spleen dysfunctions.[30]
G. olivieri Griseb.
TurkeyFlowering aerial parts, macerateLowering the blood glucose in type II diabetes (methanol extract showed potent hypoglycaemic activity) [56]
TurkeyAerial parts, raw leafWound healing[57]
Iran RootPlaster with vinegar against bites of poisonous animals and to cure infected wounds, to treat urinary retention, menstrual, liver and spleen dysfunctions.[30]
G. gelida Bieb
TurkeyFlowering aerial parts, decoctionBronchitis, uretic[58]
TurkeyAerial parts, powder (eaten with honey) or decoctionAgainst jaundice[59]
Iran RootPlaster with vinegar against bites of poisonous animals and to cure infected wounds, to treat urinary retention, menstrual, liver, and spleen dysfunctions.[30]
G. kurroo Royle
Endemic to Western and North-western HimalayasRoot and rhizome

Leaves		Stomach ache and urinary infections, fever
Oil extract applied on ulcers and fungal infections		[60]
Pabbar Valley Western HimalayasRootDiabetes, digestive disorders, toothache (root powder orally)[61]
G. moorcroftiana Wall. ex G. Don.
Indian Western HimalayasAerial parts, juiceJaundice and blood purification[62]
G. tubiflora (G. Don.) Griseb.
Indian Western HimalayasAerial parts, juiceJaundice[62]
10 species of the Section Cruciata
G. dahurica Fisch.,
G. crassicaulis Duthie ex Burk.,
G. siphonantha Maxim. ex Kusnez., G. waltonii Burk.
G. lhassica Burk.,
G. straminea Maxim.,
G. robusta King ex Hook. f.,
G. dendrologi Marq., G. tibetica King ex Hook. f.,
G. officinalis H. Smith
Qinghai–Tibet Plateau Treatment of Chi-Ba disease with symptoms of jaundice[63]

3.3. Phytochemistry of Gentiana Species Used Traditionally to Cure Wounds

Many of the useful therapeutic effects produced by the Gentiana genus compositions can be attributed to the structure–activity relationship (SAR) of these chemical compounds. This genus is characterized by the presence of various secoiridoids, iridoids, xanthones, flavonoids, terpenoids, and their glycosidic forms, which contribute to wound healing and other anti-inflammatory properties [64,65,66]. Many studies revealed the effectiveness of these metabolites in the wound-healing process via different mechanisms, for example, an increase in the stimulation of collagen production, fibroblast cell growth stimulation, and re-epithelization [67,68,69]. Several investigations on certain compounds (which also reported on various Gentiana spp.), such as isogentisin (1), isoorientin (2), mangiferin (3), lupeol (4), pinoresinol (5), syringaresinol (6), eustomoside (7), and sweroside (8) revealed their potential in wound healing and skin regeneration procedures (Figure 1, Table 2) [67,70,71,72,73,74,75]. These molecules advance skin and wound healing through a variety of mechanisms, including sweroside’s inhibition of reactive oxygen species (ROS) and increased formation of the procollagen complex [76]. According to Harish et al.’s study, lupeol increased the epithelialization rate of the incision wound via the Wnt signaling pathway via glycogen synthase kinase 3-protein [77]. Another study identified that isoorientin has an impact on skin regeneration by upregulating epidermal involucrin via activating the expression of protein kinase C, p38, and ERK 1/2 [78]. Similar findings were also reported about mangiferin’s impacts on IL-1β, TNFα, and COX-2 and an immunohistochemical marker of angiogenesis in wound healing [79].
Table
Table 2. Some of the most important compounds in seven European and Asia Minor Gentiana species (Gentiana lutea, G. punctata, G. asclepiadea, G. septemfida cruciata, G. oliverii, and G. gelida), which were found to be used in relation to wound-healing practices in traditional medicine (see Table 1). Legend: This compound is of uncertain origin and is rather an artifact of the extraction process.
Table 2. Some of the most important compounds in seven European and Asia Minor Gentiana species (Gentiana lutea, G. punctata, G. asclepiadea, G. septemfida cruciata, G. oliverii, and G. gelida), which were found to be used in relation to wound-healing practices in traditional medicine (see Table 1). Legend: This compound is of uncertain origin and is rather an artifact of the extraction process.
Iridoid and Secoiridoid Aglycones and Glycosides
luteapunctataasclepiadeaseptemfidacruciataoliveriigelida
Amarogentin Roots [80,81,82,83,84]
Leaves [83]		 Roots [85]
Amaroswerin Roots [84,86]
(-)-Gentiolactone Roots [87]
Gentioflavoside Roots [88,89]
GentiolutelinFresh roots [80]
Gentiolutelin dimethylacetal Fresh roots [80]
Gentiopicrin Aerial parts, Roots [90,91]Aerial parts [92]
6’-O- Gentiopicrin Roots [90]
Olivierigenin Aerial parts [93]
GentiopicrosideSeeds [94]
Roots
[67,83,84,86,95,96,97,98]
Leaves [83,99,100]
Flowers [101] 		Roots [88,89,97] Roots [92] Roots [92,102] Aerial parts [93]Aerial parts [103]
Olivieroside A Aerial parts [93]
Olivieroside B Aerial parts [93]
Olivieroside C Whole plant [104]
6’-O-β-D-glucosyl- gentiopicroside Whole plant [104]
Swertiapunimarin Whole plant [104]
Gelidoside Aerial parts [103]
Gentomoside Aerial parts [103]
Gentiopicroside (6-O-β-D-glucopyranoside of)Roots [105]
GentiosideRoots [106] Roots [88,89,97,107]Roots [92] (isomers)
EustomorussideLeaves [99] Whole plant [104]Aerial parts [103]
EustomosideLeaves [99] Whole plant [104]Aerial parts [103]
Iridoid A Roots [107]
Loganic acidRoots [81,95,96,100,105] Roots [107] Roots [102]
Loganin Roots [107]
TriflorosideSeeds [94] Aerial parts [108] Aerial parts [108]
Scabran G3Fresh roots [81] Aerial parts [103]
ScabranG4Fresh roots [81]
SeptemfidosideLeaves [99] Flowers [101] Whole plant [104]
SwerosideSeeds [94,95,96]
Roots [67,97]		Roots [88,89,97,109] Roots [92] Aerial parts [91] Roots [92,102] Aerial parts [92]Whole plant [104]
Sweroside (6-O-β-D-glucopyranoside)Roots [105]
SwertiamarinRoots [67,81,83,84,95,97,100]Roots [88,89,97,109] Roots [92] Aerial parts [91] Roots [92,102]
Aerial parts [92] 		Aerial parts [103]
Flavonoids
luteapunctataasclepiadeaseptemfidacruciataoliveriigelida
Homorientin Leaves [83]
Isoorientin Plant parts [89]Leaves [89,110] Aerial parts, Roots [91] Aerial parts [93,111]
Luteolin Roots [85]
Luteolin-7-O-glucoside Roots [85]
Chrysin Roots [85]
Apigenin Roots [85]
Quercetin Roots [85]
Rutoside Roots [85]
Naringenin Roots [85]
Isoorientin-4′-O-β-D-glucoside Leaves [110]
Isoorientin-2′’-O-β-D-glucoside Leaves [112]
trans-Cafeoyl- 2″-isoorientin-4′-0-β-D-glucoside Leaves [112]
trans-Feruloyl-2″-isoorientin-4′-O-β-D-glucoside Leaves [112]
IsosaponarinRoots [113]
Isosaponarin-6′’-O-β-D-xylopyranosideRoots [113]
IsovitexinLeaves [83,89,99]Leaves [89,114] Aerial parts, Roots [90,91]
Isovitexin-4′-O-glucoside Leaves [14]
Isoscoparin Leaves [112]
trans-Feruloyl-2″-isovitexin Leaves [112]
trans-Feruloyl-2′-isovitexine-4′-O-β-D-glucoside Leaves [112]
Alkaloids
luteapunctataasclepiadeaseptemfidacruciataoliveriigelida
GentianadineRoots [115] Roots [116] Aerial parts [117]
GentianineRoots [115,118] Roots [116] Roots [90] Aerial parts [117]
Gentiananine Aerial parts [119]
Oliverine Aerial parts [119]
GentioflavineRoots [118]Roots [116]
Alkaloid I Aerial parts [120]
Alkaloid IIAerial parts [120]Aerial parts [120]
Alkaloid VAerial parts [118]Aerial parts [118]
Dehydrogentioflavine Roots [116]
Gentiotibetine Roots [116] Aerial parts [119]
3,4-dihydro-1H,6H,8H-naphtho [1,2-c:4,5-c’,d’]dipyrano-1,8-dione Roots [121]
Xanthones
luteapunctataasclepiadeaseptemfidacruciataoliveriigelida
Gentianin Roots [82,97,115]
Gentisein Roots [89,122]
Fresh roots [81] 		Roots [89]
2-Hydroxygentisein Roots [89]
8-Hydroxygentisein Roots [89]
Gentisin Roots [95,122]
Fresh roots [81]
7-Hydroxy-3-methoxy-1-O-primeverosylxanthoneRoots [106]
1-Hydroxy-3-methoxy-7-O-primeverosylxanthoneRoots [106]
Isogentisin Roots [80,82,95,122]
Fresh roots [81]
Flowers [101]
Leaves [82] 		Roots [90]
Mangiferin Leaves [82,83] Aerial parts, Roots [90,91]
2,3′,4,6-TetrahydroxybenzophenoneFresh roots [81]
Lignans and related compounds
luteapunctataasclepiadeaseptemfidacruciataoliveriigelida
(–)-BerchemolFresh roots [81]
(–)-BerchemolFresh roots [81]
GentioluteolFresh roots [81]
(+)–1-HydroxysyringaresinolFresh roots [81]
(+)-FraxiresinolFresh roots [81]
(+)-1-HydroxypinoresinolFresh roots [81]
Syringaresinol 4′-O-β-D-glucopyranosideFresh roots [81]
Anofinic acidFresh roots [81]
2-Hydroxyanofinic acidFresh roots [81]
2-Methoxyanofinic acidFresh roots [81]
SyringaresinolFresh roots [81]
(+)-MedioresinolFresh roots [81]
(–)-PinoresinolFresh roots [81]
Gentiolutelin dimethylacetalFresh roots [81]
GentiolutelinFresh roots [81]
Olivieridepside Aerial parts [93]

3.4. Pharmacological Tests for Wound Healing by Gentiana Species

Although many of the world’s traditional systems, such as traditional European medicine and traditional Iranian medicine, emphasize gentian’s use in various skin and soft tissue complications, some studies have been conducted on the potential of gentian for wound healing.
Although Gentiana lutea’s most common and traditional use is to treat digestive disorders, it is worth paying attention to its many other biological effects. Mathew et al. examined the ethanol and petroleum ether rhizome extracts of G. lutea for wound-healing activity at oral doses of 300 and 500 mg/kg/day [123]. According to their findings, both extracts significantly increased the incision and excision wound models. Other research found that three secoiridoid glycosides isolated from G. lutea ssp. symphyandra (gentiopicroside, sweroside, and swertiamarine) stimulated collagen production and mitotic activity in cultured chicken embryonic fibroblasts [67]. An ethanolic extract of G. lutea rhizomes increased the activity of human keratinocyte lipid and ceramide synthesis, which is required for the formation of the epidermal barrier [124,125]. According to one study, the extracts of G. lutea root have anti-inflammatory, antiproliferative, and antifungal properties [126]. Other Gentiana species are also promising for wound cure. A methanolic extract of G. macrophylla root demonstrated notable activity against bacterial strains isolated from burn wounds with a phenolic and flavonoid content of the extract of 26.70 ± 1.5 mg gallic acid equivalent (GAE)/g·DW and 10.11 ± 0.8 mg quercetin equivalent/g·DW, respectively [127]. Research on G. scabra saw ethanolic root extract demonstrating beneficial effects on skin lesions and thickness in a mouse contact dermatitis model [128].

3.5. Conservation Status of Gentiana Species Used Traditionally to Cure Wounds

Medicinal plants associated with traditional uses are often wild-harvested, and thus ethnobotanical research should consider conservation issues. For example, it is well-known that G. lutea is still collected in the wild in the Pyrenees for medicinal uses despite legal protection [21]. Furthermore, since locals may use G. lutea and G. burseri Lap. indiscriminately, with the latter being much rarer than the former, there is also a risk of these species becoming endangered [21] (Figure 2 and Figure 3).
In the Suva Planina range, ethnobotanical research established that G. lutea has the highest Use Value [UV = 1], calculated as a quotient of number of citations per species and number of informants, which indicates a strong anthropogenic pressure on this species in Serbia as well [19] (Figure 2). It is dried and sold in the mountain villages of Peshkopia, Eastern Albania [26]. The situation is similar in other parts of its range [46]. Wild yellow gentians are also collected to sell in Italy [129]. In addition, high UV is reported for G. lutea subsp. symhyandra in Bosnia and Herzegovina [45] where this taxon is evaluated as endangered (Figure 2).
Many gentians are declining in population and have a high International Union for Conservation of Nature (IUCN) conservation status in several European countries, but in others, they are considered Least Concerned and are not even listed in the Red Data books (Figure 2, Figure 3, Figure 4 and Figure 5). Populations of Gentiana lutea as well as G. punctata are declining in most territories of Europe (Figure 2 and Figure 3). G. lutea subsp. lutea L. is rare in Romania and Slovenia, where it is evaluated as Endangered, and in Portugal, where it is Critically Endangered [130] (Figure 2).
The typical subspecies has the Least Concern IUCN category, for instance, in the Czech Republic [131] and according to the European Environmental Agency, basically for most of the territory of Europe. However, this information needs revision because in Italy, G. lutea. subsp. lutea is considered Near Threatened, and in Sardinia, it is Endangered [132]. This subspecies does not occur in Bulgaria (although it is listed as Least Concerned) [130], and the only taxon growing in the mountains there is G. lutea subsp. symhyandra (Murb.) Hayek, which is evaluated as Endangered [133]. It is protected by the Biodiversity Act of the country but still collected in the wild by poachers according to Peev and coauthors [134] and Kozuharova (pers. comm. with a ranger in Pirin National Park in 2022).
G. asclepiadea is considered common in Bulgaria (and has not been evaluated in accordance with IUCN criteria). However, the popularity of this plant has led to instances of overharvesting, and it is now strictly protected in Poland [135], (Figure 4). Other gentians, such as G. cruciata (see Figure 5) and G. pneumonanthe (not shown), are considered common and thus are not evaluated in Bulgaria, Greece, Bosnia and Herzegovina, Italy, etc., but they are rare and threatened in the territory of other European countries (Figure 5) with all the consequences for biodiversity as gentians are host plants for highly specialized Blue Butterflies [136,137,138,139,140,141,142,143,144].

3.6. Cultivation and Micropropagation of Gentiana Species Used Traditionally to Cure Wounds

G. lutea has been cultivated in France for years [145]. Based on the ethnobotanical research in the mountain regions of the Pirot District, Serbia (Table 1), the cultivation of G. lutea and G. cruciata ought to be possible, due to the similarity of natural habitats in both France and Serbia. Thus, it could support the conservation of the wild populations and improve the living standard of the rural communities in the area [38]. As a result, the cultivation of G. lutea has been in progress for six years in Mount Tara (Serbia) [146].
Based on bioecological studies of G. lutea subsp. symhyandra in Bulgaria, Peev et al. (2018) concluded that this plant needs to be cultivated under conditions closely matching those of the natural habitats [134]. Micropropagation methods have already been developed for G. pneumonanthe [147], G. kurroo, G. cruciata, G. pannonica, and G. tibetica using somatic embryos [80], or by organogenesis for 11 other species (G. acaulis, G. lutea, G. purpura, G. cruciata, G. cerina, G. corymbifera, G. kurroo, G. punctata, G. tibetica, G. pneunomonante, and G. triforia [148]. There are no publications, other than two, about G. asclepiadea, published by Zając and Pindel [134,135,149]. Shoot multiplication of G. kurroo was achieved in vitro using shoot tips and nodal segments as explants [150]. An efficient protocol for callus regeneration and micropropagation has been developed [151].

4. Conclusions

There is rich traditional knowledge on the properties of gentians to cure various skin and soft tissue complications. However, only a few modern pharmacological studies have been performed to test this wound-healing potential. Nevertheless, they confirm the traditional practice to use gentians for wound healing. Limitations appeared also to be the insufficient phytochemical studies of some Gentiana species. Our review indicates that this field deserves further investigation. Many gentians are a declining species and have high IUCN conservation status. This is another limitation. However, our study points to prospects in cultivation and micropropagation methods, which are promising solutions for the development of new drugs based on gentian extracts.

Author Contributions

Conceptualization, E.K., A.P. and Z.N.; methodology, E.K., A.P., P.K., D.B., A.F. and Z.N.; software, A.F.; validation, A.P., A.H. and I.A.; investigation, D.B., P.K., E.K., A.H., A.P., Z.N. and A.F.; writing—original draft preparation, E.K. and A.P.; writing—review and editing, A.P., E.K. and P.K.; visualization, A.F.; supervision, E.K.; project administration, V.D. and I.A.; funding acquisition, V.D. All authors have read and agreed to the published version of the manuscript.

Funding

This study was conducted with the help of the project “Conservation of European Biodiversity through Exploitation of Traditional Herbal Knowledge for the Development of Innovative Products”, Horizon 2020, H2020-MSCA-RISE-2018, Proposal number: 823973, and Proposal acronym: EthnoHERBS.

Institutional Review Board Statement

Not applicable.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Candidate Gentian compounds with skin regeneration and wound-healing potential. isogentisin (1), isoorientin (2), mangiferin (3), lupeol (4), pinoresinol (5), syringaresinol (6), eustomoside (7), and sweroside (8).
Figure 1. Candidate Gentian compounds with skin regeneration and wound-healing potential. isogentisin (1), isoorientin (2), mangiferin (3), lupeol (4), pinoresinol (5), syringaresinol (6), eustomoside (7), and sweroside (8).
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Figure 2. Map of distribution of G. lutea—conservation status and medicinal use, Legend: IUCN status—Least Concern (LC); Near Threatened (NT); Vulnerable (VU); Endangered (EN); Critically Endangered (CR); and Not Evaluated (NE).
Figure 2. Map of distribution of G. lutea—conservation status and medicinal use, Legend: IUCN status—Least Concern (LC); Near Threatened (NT); Vulnerable (VU); Endangered (EN); Critically Endangered (CR); and Not Evaluated (NE).
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Figure 3. Map of distribution G. punctata and G. burseri—conservation status and medicinal use, Legend: IUCN status—Least Concern (LC); Near Threatened (NT); Vulnerable (VU); Endangered (EN); Critically Endangered (CR); and Not Evaluated (NE).
Figure 3. Map of distribution G. punctata and G. burseri—conservation status and medicinal use, Legend: IUCN status—Least Concern (LC); Near Threatened (NT); Vulnerable (VU); Endangered (EN); Critically Endangered (CR); and Not Evaluated (NE).
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Figure 4. Map of distribution G. asclepiadea—conservation status and medicinal use, Legend: IUCN status—Least Concern (LC); Near Threatened (NT); Vulnerable (VU); Endangered (EN); Critically Endangered (CR); and Not Evaluated (NE).
Figure 4. Map of distribution G. asclepiadea—conservation status and medicinal use, Legend: IUCN status—Least Concern (LC); Near Threatened (NT); Vulnerable (VU); Endangered (EN); Critically Endangered (CR); and Not Evaluated (NE).
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Figure 5. Map of distribution G. cruciata—conservation status and medicinal use, Legend: IUCN status—Least Concern (LC); Near Threatened (NT); Vulnerable (VU); Endangered (EN); Critically Endangered (CR); and Not Evaluated (NE).
Figure 5. Map of distribution G. cruciata—conservation status and medicinal use, Legend: IUCN status—Least Concern (LC); Near Threatened (NT); Vulnerable (VU); Endangered (EN); Critically Endangered (CR); and Not Evaluated (NE).
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Pasdaran, A.; Naychov, Z.; Batovska, D.; Kerr, P.; Favre, A.; Dimitrov, V.; Aneva, I.; Hamedi, A.; Kozuharova, E. Some European Gentiana Species Are Used Traditionally to Cure Wounds: Bioactivity and Conservation Issues. Diversity 2023, 15, 467. https://doi.org/10.3390/d15030467

AMA Style

Pasdaran A, Naychov Z, Batovska D, Kerr P, Favre A, Dimitrov V, Aneva I, Hamedi A, Kozuharova E. Some European Gentiana Species Are Used Traditionally to Cure Wounds: Bioactivity and Conservation Issues. Diversity. 2023; 15(3):467. https://doi.org/10.3390/d15030467

Chicago/Turabian Style

Pasdaran, Ardalan, Zheko Naychov, Daniela Batovska, Philip Kerr, Adrien Favre, Vladimir Dimitrov, Ina Aneva, Azadeh Hamedi, and Ekaterina Kozuharova. 2023. "Some European Gentiana Species Are Used Traditionally to Cure Wounds: Bioactivity and Conservation Issues" Diversity 15, no. 3: 467. https://doi.org/10.3390/d15030467

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