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Review
Artemisia absinthium L.—Importance in the History
of Medicine, the Latest Advances in Phytochemistry
and Therapeutical, Cosmetological and Culinary Uses
Agnieszka Szopa 1, * , Joanna Pajor 1, Paweł Klin 2, Agnieszka Rzepiela 3,
Hosam O. Elansary 4,5,6 , Fahed A. Al-Mana 4, Mohamed A. Mattar 7and Halina Ekiert 1, *
1Chair and Department of Pharmaceutical Botany, Medical College, Jagiellonian University, Medyczna 9,
30-688 Kraków, Poland; asiek.pajor@student.uj.edu.pl
2Family Medicine Clinic, Medizinisches Versorgungszentrum (MVZ) Burgbernheim GmbH,
Gruene Baumgasse 2, 91593 Burgbernheim, Germany; bag-burgbernheim@gmx.de
3Museum of Pharmacy, Medical College, Jagiellonian University, Floria´nska 25, 31-019 Kraków, Poland;
agnieszka.rzepiela@uj.edu.pl
4Plant Production Department, College of Food and Agriculture Sciences, King Saud University,
Riyadh 11451, Saudi Arabia; helansary@ksu.edu.sa (H.O.E.); falmana@ksu.edu.sa (F.A.A.-M.)
5
Floriculture, Ornamental Horticulture, and Garden Design Department, Faculty of Agriculture (El-Shatby),
Alexandria University, Alexandria 21545, Egypt
6Department of Geography, Environmental Management, and Energy Studies, University of Johannesburg,
APK Campus, Johannesburg 2006, South Africa
7Department of Agricultural Engineering, College of Food and Agriculture Sciences, King Saud University,
Riyadh 11451, Saudi Arabia; mmattar@ksu.edu.sa
*Correspondence: a.szopa@uj.edu.pl (A.S.); halina.ekiert@uj.edu.pl (H.E.); Tel.: +48-(12)-6205436 (A.S.);
+48-(12)-6205430 (H.E.); Fax: +48-(62)-05440 (A.S.); +48-(62)-05440 (H.E.)
Received: 14 July 2020; Accepted: 12 August 2020; Published: 19 August 2020
Abstract:
Artemisia absinthium—wormwood (Asteraceae)—is a very important species in the history
of medicine, formerly described in medieval Europe as “the most important master against all
exhaustions”. It is a species known as a medicinal plant in Europe and also in West Asia and
North America. The raw material obtained from this species is Absinthii herba and Artemisiae absinthii
aetheroleum. The main substances responsible for the biological activity of the herb are: the essential
oil, bitter sesquiterpenoid lactones, flavonoids, other bitterness-imparting compounds, azulenes,
phenolic acids, tannins and lignans. In the official European medicine, the species is used in both
allopathy and homeopathy. In the traditional Asian and European medicine, it has been used as
an effective agent in gastrointestinal ailments and also in the treatment of helminthiasis, anaemia,
insomnia, bladder diseases, difficult-to-heal wounds, and fever. Today, numerous other directions
of biological activity of the components of this species have been demonstrated and confirmed by
scientific research, such as antiprotozoal, antibacterial, antifungal, anti-ulcer, hepatoprotective,
anti-inflammatory, immunomodulatory, cytotoxic, analgesic, neuroprotective, anti-depressant,
procognitive, neurotrophic, and cell membrane stabilizing and antioxidant activities. A. absinthium is
also making a successful career as a cosmetic plant. In addition, the importance of this species as a
spice plant and valuable additive in the alcohol industry (famous absinthe and vermouth-type wines)
has not decreased. The species has also become an object of biotechnological research.
Keywords:
wormwood; chemical composition; biological activity; traditional applications; modern
applications; safety of use
Plants 2020,9, 1063; doi:10.3390/plants9091063 www.mdpi.com/journal/plants
Plants 2020,9, 1063 2 of 33
1. Introduction
Over the past few years, there has been an increase in interest in research on the chemistry and
biological activities of Artemisia species. This is undoubtedly connected with the awarding of the Nobel
Prize in Medicine in 2015 for the discovery of artemisinin—a sesquiterpenoid lactone effective in the
treatment of malaria, found in Artemisia annua (annual mugwort). A commonly known species of the
genus Artemisia, with an important place in the history of medicine, is Artemisia absinthium L.
The aim of this work was the review of the latest literature reports on A. absinthium in order
to evaluate the importance of this species in the traditional phytotherapy, as well as in the modern
medicine. The emphasis was put on the latest biological activities confirmed by scientific studies.
The applications in the cosmetology and in the food industry were also announced. Moreover, the
studies on the safety of use as well as the biotechnological researches were reported.
The information about A. absinthium was collected collected from various sources such as official
websites e.g., The Plant List, GBIF (Global Biodiversity Information Facility), WHO (World Health
Organization), FDA (Food and Drug Administration), EFSA (European Food Safety Authority), EMA
(European Medicines Agency), CosIng (Cosmetic Ingredient database), classical books, databases
of scientific journals (e.g., Scopus, PubMed, Google Scholar), on-line books, and pharmacopoeias.
In addition, professional historical descriptions of this species were also analyzed.
A. absinthium has its natural habitats in Europe, West Asia, and North Africa. The species has been
used for centuries as effective in various gastrointestinal ailments and in the treatment of helminthiases.
Contemporary pharmacological studies have focused on confirming and determining the mechanisms of
these traditional directions of activity. They have also demonstrated new, previously unknown possible
therapeutic applications resulting from proven antiprotozoal, antibacterial, antifungal, anti-ulcer,
hepatoprotective, anti-inflammatory, immunomodulatory, cytotoxic, analgesic, neuroprotective,
anti-depressant, procognitive, neurotrophic, cell membrane stabilizing, and antioxidant effects.
Furthermore, A. absinthium has today an important place in the production of cosmetics. It also
has an established position in the food industry, as a base for alcoholic beverages and as a spice. It has
also become an object of biotechnological research.
Recent years have seen publication of review articles on this species. However, they present the
existing, broad knowledge on its therapeutic values in a very general way [1,2].
While compiling this review, every effort was made to present in detail the qualities of this species,
with particular emphasis on the current work on the chemistry of the plant, on the chemistry of its
essential oil, its variability in chemical composition, mechanisms of action in the traditional applications
and new directions of biological activities confirmed by scientific research, as well as current views
on the safety of using this plant species. Additionally, the position of the plant in food industry and
cosmetic industry was underlined and biotechnology investigations were presented.
2. General Information on the Species
Artemisia absinthium L.—wormwood (Asteraceae), is an herbaceous plant. This species has
numerous (about 20) synonymous Latin names. The most common synonyms are: Absinthium majus
Garsault [
3
–
5
] and Absinthium officinale Brot. [
3
–
5
], Absinthium officinale Lam. [
6
], Absinthium vulgare (L.)
Lam. [3,4]Absinthium vulgare Gaertn. [6], Artemisia absinthia St.-Lag. [3,4]. Among the English names,
the most popular is “wormwood”. It comes from the German word “wermet” meaning “keeping a
clear mind” [
7
]. Some other English and foreign names are: absinth, absinth wormwood, absinthe,
absinthium, Maderwood (English, USA), Absinth, Bitterer Beifuss, Wermkraut, Wermut, Wermutkraut,
Wurmkraut (German), absinthe, grande absinthe, Herbe d’absinthe (French), Majri, Mastiyarah (Hindi),
Yang ai, zhong ya ku hao (Chinese) [
1
,
2
,
6
,
8
–
11
]. A. absinthium is a shrub-like perennial plant growing
to a height of 80 cm. In some habitats, it even reaches a height of up to 1.5 m. The whole plant is
strongly pubescent and has an intense, sharp smell [
1
,
7
,
12
]. A. absinthium leaves have essential oil
secreting hairs/glandular trichomes and covering T-hairs that have a protective function—they protect
the plant against high temperatures and prolonged drought [7,13].
Plants 2020,9, 1063 3 of 33
The stem is grey-green, strongly pubescent and ribbed—it usually has 5 flattened, longitudinal
furrows [1,7,12]. The part of the stem with flowers reaches a diameter of no more than 2.5 mm [12].
The leaves also take on a grey-green color and are densely pubescent on both sides [
1
,
7
]. Their shape
depends on where they are situated on the plant. The basal leaves have long petioles, and their blade
is triangular or oval, bi- or tripinnatisect, the lower leaves are not as intensely divided, and the top
leaves are lanceolate [12].
The capitulum inflorescences are gathered in loose panicles growing from the axils of the leaves.
In these semicircular or circular heterogamous capitulum there are light-yellow ligulate female flowers,
and tubular hermaphroditic flowers. The involucral bracts covering the capitulum are long and grey,
with ensiform outer and oval inner leaves [
1
,
12
] The flowering period of the plant in Central Europe
begins towards the end of July and lasts until October [7,12].
The fruit is a small achene with brown stripes.
A. absinthium comes from Europe, West Asia and North Africa. It is a species commonly found in
Poland, Scotland and England. The species was introduced and acclimatized in North America and
South America; it can also be found in Australia. In Kashmir, populations of A. absinthium occupy
sites at an altitude of up to 2100 m. It occurs on roadsides, forest felling sites and clearings, as well as
wasteland and stony ground [1,6,7,10,14].
A. absinthium reproduces mainly vegetatively by roots [
7
]. This species is not susceptible to
pathogens, but the roots are sensitive to excessive irrigation, which quickly leads to rotting [7].
A. absinthium is a species cultivated today in the countries of southern Europe, the USA and Brazil.
The harvesting period begins with the appearance of the first flowers. Leafy shoots and basal
leaves are cut off, while the woody parts are left behind. Harvesting can be done several times a year.
The drying process has a significant impact on the quality of A. absinthium essential oil. It has
been observed that even slight heating of the air affects the organoleptic characteristics of the oil.
In addition, the collected herb should not be spread in a thick layer because it then dries very slowly.
Drying should be carried out in shaded airy rooms or drying chambers at room temperature [15].
3. Phytochemical Characteristics
A. absinthium contains numerous compounds responsible for its biological activities. The herb of
this species is considered to be the raw material for oil extraction. The essential oil content of the herb
varies both qualitatively and quantitatively depending on the geographical region and environmental
conditions (Table 1). The concentration of oil in the plant ranges from 0.2% in a dry climate to 1.5% in a
humid climate [
16
]. The highest concentration of essential oil in A. absinthium herb is observed in June
and July [
15
]. To indicate the main component of the oil is difficult because the results of phytochemical
tests are not conclusive. The most frequently listed compounds are thujyl alcohol esters,
α
-thujone,
β
-thujone, camphene,
α
-cadinene, guaiazulene (Z)-epoxyocimene, (E)-sabinyl acetate, (Z)-chrysantenyl
acetate [
1
,
16
] (Figure 1). It has been noted that among populations growing in areas above 1000 m a.s.l.
α-thujone is the characteristic compound, while (Z)-epoxyocimene dominates below this height [16].
Figure 1. Cont.
Plants 2020,9, 1063 4 of 33
Figure 1.
Chemical structure of volatile compounds characteristic for A. absinthium herbal essential oil.
The concentration and composition of A. absinthium essential oil from plants growing in Poland
were tested in 2007. In the flowering herb of plants collected from an area in the Mr ˛agowo District
(North-East part of Poland), the essential oil content ranged from 0.90% to 1.45%. The concentration
of the oil in plants in the vegetative stage was lower and amounted to 0.60–0.94%. The compounds
isolated in the largest quantities were: sabinyl acetate, chrysantenyl acetate,
β
-thujone, and cineol [
17
].
Table 1. The chemical composition of A. absinthium essential oil.
Chemical Groups/Compounds References
Monoterpenoids
(E)-6,7-epoxyocimene, (Z)-6,7-epoxyocimene, (Z)-carveol, carvacrol, geranyl pentanoate,
geranial, p-menth-3-en-9-ol, neryl acetate [18]
(E)-epoxyocimene [19]
(Z)-epoxyocimene [16,19]
1,8-cineole [1,16–25]
geranyl 2-methylbutanoate, neryl 2-methylpropanoate, linalyl 3-methylbutanoate, geranyl
3-methylbutanoate, bornyl 3-methylbutanoate, linalyl butanoate, (Z)-β-epoxyocimene,
fenchone, (E)-sabinene hydrate, isobornyl acetate, isobornyl propanoate, pulegone,
α-fenchene
[23]
neryl 2-methylbutanoate [21,23]
2-β-pinene, lyratyl acetate [25]
linalyl 3-methylbutanoate [18,23]
neryl 3-methylbutanoate [21,23]
terpinene-4-ol, (E)-sabinene hydrate, (E)-sabinol [22,23]
thujyl alcohol [1,21]
allo-ocimene [18,20]
Plants 2020,9, 1063 5 of 33
Table 1. Cont.
Chemical Groups/Compounds References
Artemisia ketone, 3-methylbutanoate, (E)-thujone, phellandrene, isothujyl acetate, pinene,
(E)-verbenol, (Z)-thujone [21]
borneol, (Z)-nerolidol, (Z)-verbenol, (E)-β-ocimene, (Z)-sabinene hydrate, α-terpinyl
acetate, p-cymen-8-ol, terpinolene, α-terpinene [22]
chrysanthenol [19,24]
(Z)-chrysanthenol [15,26]
(Z)-expoxyocimene [15,21,24,26]
phellandrene epoxide, thujol [18,24]
eugenol [18,22,23,27]
geraniol [1,18,22,27]
iso-3-thujanol [27]
geranyl isovalerate, lavandulyl acetate, allo-ocimene, β-linalool [20]
camphene [1,19,22,23]
camphor [16,22–24,26,28]
carvone [21,22]
lavandulol [20,22–24]
limonene [22–25]
linalool [18,19,21–24,26]
myrcene [16,21]
neral, geranyl acetate, neryl acetate, (Z)-β-ocimene [18,22]
nerol [16,18,21,22,27]
bornyl acetate [15,22–24]
chrysanthenyl acetate [15,16,21,24,26,27]
(Z)-chrysanthenyl acetate [16,18]
linalyl acetate [16,22–24]
sabinyl acetate [15,18,20,22,24]
(E)-sabinyl acetate [16,21,23,28]
thujyl acetate [1]
p-cymene [1,16,18,22,23]
linalyl propionate [23,24]
sabinene [18,20–24]
thymol [24]
santolinatriene [23,25]
(Z)-linalooloxide [22–24]
(E)-linalool oxide [22,24]
epoxyocymene [21,24]
tricyclene [29]
α-phellandrene [16,18,20,23]
α-pinene [1,16,18,19,22–25]
α-terpineol [1,18,20,24,25]
α-thujene [18,22,23]
α-thujone [1,15,16,18,23,24,30]
β-phellandrene [1,18,22]
β-myrcene [18–20,23,28]
β-pinene [16,21–23,28]
β-thujone [1,15,18,20,23,24,27,
28,30,31]
γ-terpinene [18,20,22,23]
Sesquiterpenoids
(E)-nerolidol, ar-curcumene, diepi-α-cedrene, bisabolol oxide, α-copaene, β-gurjunene [18]
(E,E)-farnesyl acetate, (E,E)-farnesal, (Z,E)-α-farnesene, (E,E)-farnesyl 3-methylbutanoate,
7-
α
-silphiperfol-5-ene, allo-aromadendrene, bicyclogermacrene, (Z)-
α
-bisabolene, cyperene,
epi-
β
-santalene, hexahydrofarnesyl acetone, petasitene, pethybrene, presilphiperfol-7-ene,
(E)-nerolidyl propanoate, silfinen-1-en, silphiperfol-6-ene, humulene oxide II, α-cedrene,
α-gurjunene, α-isocomene, α-santalene, α-(E)-bergamotene, β-bisabolene, β-eudesmol,
β-isocomene, β-santalene, γ-humulene
[23]
Plants 2020,9, 1063 6 of 33
Table 1. Cont.
Chemical Groups/Compounds References
elemol, guaiazulene, cadinene, α-himachalene [1]
germacrene D [16,19,22,26]
caryophyllene [1,24]
curcumene [21]
nerolidol, (E)-β-farnezene [25]
spathulenol [18,27]
bisabololoxide B [27]
caryophyllene oxide [1,21–25,27]
(E)-caryophyllene [26]
α-bisabolene, α-calacorene, γ-curcumene, γ-muurolene [22]
α-bisabolol [18,22,23,27]
α-humulene [18,22,23]
α-copaen [22,23]
β-bourbonene [18,23]
β-elemene [19,23]
β-caryophyllene [18–20,23]
β-selinene [18,22–24,26]
γ-gurjunene [18,23]
γ-cadinene [18,22]
δ-cadinene [18,23,25]
Diterpenoids
1-(E)-8-isopropyl-1,5-dimethyl-nona-4,8-dienyl-4-methyl-2,3-dioxa-bicyclo(2, 2, 2)oct-5-ene,
iso-1-(E)-8-isopropyl-1,5-dimethyl-nona-4,8-dienyl-4-methyl- 2,3-dioxa-bicyclo(2, 2,
2)oct-5-ene
[1,32]
vulgarol A, vulgarol B [18]
Phenylpropanoids
methyleugenol [27]
estragole [27]
Other important compounds of the herb of A. absinthium are bitter sesquiterpenoid lactones [
15
],
of which the main metabolite is a guaianolide dimer—absinthin (0.2–0.28%) (Table 2). Other compounds
are found in high concentration such as absinthin isomers—anabsinthin, anabsin, artabsin (0.04–0.16%),
and absintholide (Figure 2) [
16
]. The highest concentration of bitter components is obtained from
plants harvested in September [
15
]. Other bitter compounds that have been isolated from the plant
include artamaridinin, artamarin, artamarinin and artamaridin [21].
A. absinthium extracts contain high concentrations of blue chamazulene [
18
,
21
–
23
,
26
,
28
]—a
compound from the group of azulenes, resulting from the transformation of sesquiterpenoid matrix [
33
].
Other azulenes isolated from the herb are 3,6-dihydrochamazulene, 7-ethyl-1,4-dimethylazulene [
19
],
7-ethyl-5,6-dihydro-1,4-dimethylazulene, dihydrochamazulene isomer [
16
], prochamazulenogen [
21
],
and azulene [1,21].
The plant also contains numerous flavonoids, including: quercetin, kaempferol, apigenin,
artemethin, and rutoside [
1
,
16
,
21
,
22
,
34
,
35
], and numerous phenolic acids such as: chlorogenic, ferulic,
gallic, caffeic, syringic, and vanillic, and derivatives of caffeoylquinic acid [16,21,36,37].
Other compounds found in smaller amounts are the chalcone—cardamonin [
38
,
39
], coumarins
(herniarin, coumarin) [
22
,
27
], fatty acids [
1
], tannins [
16
,
21
,
31
], carotenoids, lignans [
16
,
21
] and resinous
substances [31].
Four new, previously unknown structures have been isolated from A. absinthium
herb by Javed et al.; they were glycosidic esters: 3,11-dimethyldodecan-1,7-dioic
acid-1-
β
-D-glucopyranosyl-6
0
-octadec-9
00
-enoate, lanost-24-en-3
β
-ol-11-one-28-oic acid-21,23
α
-olide-3
β
-D-glucopyranosyl-2
0
-dihydrocaffeoate-6
0
-decanoate, stigmast-5,22-dien-3
β
-ol-21-oic acid
-3
β
-glucopyranosyl-2
0
-octadec-9
00
-enoate, and tricosan-14-on-1,4-olide-5-eicos-9
0
-enoate. The authors
Plants 2020,9, 1063 7 of 33
classified the first two compounds as sterols, while the other two compounds could not be classified
into a specific group of metabolites [40].
The composition of A. absinthium extract depends on the extractant used. It has been proved that
an ethanolic extract has a significantly higher concentration of flavonoids, phenols and tannins in
comparison with aqueous and chloroform extracts [31].
Figure 2. Chemical structure of sesquiterpenoid lactones characteristic for A. absinthium.
Table 2. The chemical composition of A. absinthium herb.
Chemical Group Compound References
Sesquiterpenoid
lactones
absintholide [9,16]
absinthin [1,9,15,16,21,31]
anabsin, ketopepenolid-A, β-santonin [16]
anabsinthin [16,21,31]
arabsin, ketopelenolide, santonin related lactones [21]
artabin [16,21]
artabsin [15,16,21]
artenolide, deacetyloglobicin, isoabsinthin, parishine B and C [9]
germacranolide, hydroxypelenolide [34]
caruifolin D [41]
matricin [9,16]
Bitter principles 24-zeta-ethylcholesta-7,22-dien-3-β-ol, artamaridin, artamaridinin,
artamarin, artamarinin, quebrachitol [21]
Azulenes
3,6-dihydrochamazulene [26]
7-ethyl-1,4-dimethylazulene [19]
7-ethyl-5,6-dihydro-1,4-dimethylazulene [16]
azulene [1,21]
chamazulene [18,21–23,26,28]
dihydrochamazulene isomer [16]
prochamazulenogen [21]
Plants 2020,9, 1063 8 of 33
Table 2. Cont.
Chemical Group Compound References
Flavonoids
quercetin-3-rutinoside [36]
5,6,320,50-tetramethoxy 7,40-hydroxyflavone [21,42]
5-hydroxy-3,30,40,6,7-pentamethoxyflavone, glycosides of quercetin [21]
apigenin, quercetin dihydrate, flavone, kaempferol, catechin, myristin,
naryngenin [22]
artemetin [1,21,34]
Artemisia bis-isoflavonyl dirhamnoside, Artemisia isoflavonyl glucosyl
diester [1]
casticin [34]
quercetin [16]
rutoside [16,21]
Chalcones cardamonin [38,39]
Coumarins herniarin [27]
coumarin [22]
Phenolic acids
10,30-O-dicaffeoylquinic acid, 10,50-O-dicaffeoylquinic acid,
30,50-O-dicaffeoylquinic acid, 40,50-O-dicaffeoylquinic acid,
50-O-caffeoylquinic acid
[37]
chlorogenic acid [16,21,36,37]
ferulic acid [22,31]
gallic acid [22,35]
caffeic acid [16,21,22,31,35]
coumaric acid, salicylic acid [16]
p-coumaric acid, rosmarinic acid, tannic acid [22]
syringic acid, vanillic acid [16,22]
Organic acids succinic acid, malic acid, (E)-cinnamic acid [22,31]
Fatty acids
9- hydroxy-(E)-10,12-octadecadienoic acid, 13- hydroxy-(E),(E)-9,
11-octadcadienoic acid, epoxyoleic acid, linoleic acid, oleic acid,
palmitic acid, stearic acid
[1]
dodecanoic acid [18]
Sterols
3,11-dimethyldodecan-1,7-dioic acid-1-β-D-glucopyranosyl-60-
octadec-900 -enoate, lanost-24-en-3β-ol-11-one-28-oic acid-21,23
α-olide-3β-D-glucopyranosyl-20-dihydrocaffeoate-60- decanoate
[40]
Fatty acid glycosides ethyl linoleate, methyl linoleate, ethyl palmitate, methyl palmitate [23]
Tannins nd * [16,21,22,31]
Lignans nd [16,21]
Carotenoids nd [16,21]
Resinous substances nd [31]
Polysaccharides nd [43]
Other compounds
(5Z)-2,6-dimethylocta-5,7-diene-2,3-diol [19]
(Z)-2,6-dimethylocta-5,7-diene-2,3-diol [24,26]
(Z)-jasmone, 2-ethyl-4-methyl-1,3-pentadienylbenzene, 3-octanol,
bicyclo[2.2.1]-hept-2-en-7-ol, (E)-3-hexenyl butyrate, (Z)-3-hexenyl
butyrate, benzeneacetaldehyde, fraganol, 3,7-dimethyl-2-metyl
propanoic acid
[18]
1H-benzocycloheptene, 4-hexen-1-ol, benzenemethanol, benzene,
1-butanol, en-in-dicycloether, (E)-photonerol, [25]
(E)-nuciferyl 2-methylpropanoate, albene, (E)-nuciferyl butanoate,
hexanal, (Z)-nuciferyl propanoate [23]
trimethoxybezoic acid [1]
(E)-3-hexenyl butyrate [19,26]
nuciferol butanoate, nuciferol propionate [21]
silica [31]
stigmast-5,22-dien-3β-ol-21-oic acid-3β-glucopyranosyl-20-
octadec-900 -enoate, tricosan-14-on-1,4-olide-5-eicos-90-enoate [40]
* nd—no data.
Plants 2020,9, 1063 9 of 33
4. Importance of A. absinthium in the History of Medicine
Wormwood has always been associated with a very bitter taste. In the Polish language, it is the
proverbial quintessence of bitterness (in the popular saying “bitter as wormwood”), but already in
ancient Greece it owed its name—
αψ´
ινθι
o
ν
, Apsinthion (Latin Apsinthium)—to its not very pleasant
taste. Dioscorides (1st century AD) and Theophrastus (4th/3rd century BC) associated it with the Greek
words “
á
psinthos”—unpleasant, disagreeable, or “
á
pinthos”—unfit for drinking. In the Germanic
literature on herbal medicine, the name “Wermut” appears, indicating the antiparasitic effect of this
herb attributed to its bitter taste (“Werm” in Old German means “worm”) [
44
]. In Dioscorides’s
De materia medica, wormwood, usually taken in the form of tincture, is described as having warming,
astringent and stimulating effects, being able to relieve stomach and abdominal pains, and effective
against poison [
45
]. Pliny the Elder (1st century AD) also recommends Absinthium as a hypnotic,
laxative, menstruation-inducing agent, healing “fistulas on the eyes”, and even as a cosmetic—the
ash from it combined with a rose ointment “blackens the hair” [
46
]. The therapeutic spectrum of
wormwood (Artemisia absinthium) is very similar to that of mugwort (Artemisia vulgaris), together with
which it has often been described [
47
]; compared to mugwort, wormwood has a slightly stronger
effect on the digestive system [
48
]. Apart from the characteristic bitterness, another special property of
wormwood has been known since antiquity—depending on the dose, it stimulates the central nervous
system, causing even epileptic seizures and hallucinations [
49
]. Both Walafrid Strabo in his “Hortulus”
(9th centuryAD) and Hildegard von Bingen in “Physica” three centuries later emphasize the restorative
effect of wormwood [
50
]. Hildegard, the famous mystic, saint and Doctor of the Church, praises
wormwood as “the most important master against all exhaustions” [
51
]. The authors of the Renaissance
era, describing the therapeutic indications for wormwood, put the main emphasis on ailments of the
digestive system. Adam Lonitzer (1551) recommends it for “strengthening the stomach” and “improving
appetite”, and Leonard Fuchs (1543) for “removing stool, winds, and pain in the gut”. Nota bene, Fuchs’s
work begins with a description of vermouth. Both authors introduce eye compresses, which are to
remove eye hyperaemia and improve eyesight [
52
,
53
]. The Polish herbals by Stefan Falimirz [
54
]
and Marcin from Urz˛ed
ó
w mention the detoxifying and restorative, as well as curative, effects of
wormwood in gastrointestinal, liver, and biliary tract diseases; it was also supposed to cure skin, ear
and eye diseases, remove odour from the mouth, and “drive out worms” [
55
]. A similar application
is given in the famous Herbiarz (herbal) by Szymon Syreniusz (1613) [
56
]. In turn, the great work
of Tabernaemontanus, Neuw Kreuterbuch (1588), in which the description of herbs also begins with
vermouth, as part of the development of a holistic way of thinking and treatment in medicine, sees
the benefit of the choleretic action of wormwood, both in the treatment of jaundice and “in angry
women who are full of bile” [
57
]. In the declining years of that philosophy, consistently supplanted by
the emerging modern medicine, Joachim Zedler in his Universal-Lexicon (1732) praises wormwood
mouthwash solutions as able to improve the smell of breath and to strengthen the gums and teeth [
58
].
This indicates a tendency to rediscover hygiene and to use those properties of wormwood that in
evidence-based medicine (EBM) are termed “antiseptic” [
59
]. Based on the essential oil of wormwood, a
very popular alcoholic drink—absinthe—was created in the 19
th
century, an intoxicant whose excessive
consumption leads to irreversible damage to the central nervous system. Because of this effect, modern
medicine prohibits the consumption of the ethereic oil obtained from this plant, or any spirit based
on wormwood, but sees the benefits of its action on the digestive system in the form of a herb [
60
].
The folk use of wormwood also deserves a mention: added to washing, its smell is supposed to repel
moths, lice, and bed bugs. The same intense smell, also released during the burning of this plant, was
the basis of its ritual use in funeral processions and in repelling evil spirits [
61
]. In folk medicine,
wormwood was used for fever, having been poured over with aqua vitae (spirit), or soaked with
pepper in vodka, wine or water, and for stomach pain [
62
], while in folk veterinary medicine, cooked
wormwood was given to cattle to improve their appetite [63].
Plants 2020,9, 1063 10 of 33
5. Application in Traditional Medicine
A. absinthium is one of the most recognizable species of the genus Artemisia in the world.
In European folk medicine, this plant has been used for millennia for many different diseases, in
particular for parasitic diseases and digestive ailments, and when fever occurred [
7
]. According to the
recommended traditional use, the leaves are used to lower the temperature, and the flowers help in
diseases of the stomach and helminthiases. A. absinthium tincture is valued as a tonic and digestive
aid [
1
]. The wormwood herb has been used to treat jaundice, constipation, obesity, splenomegaly, and
also to treat anaemia, insomnia and bladder diseases. It has also served as a remedy for injuries and
non-healing wounds [
1
]. The plant has been used as a base for preparing ointments and balms for use
on the skin [
7
]. The pharmacological activity of this species in indications such as anaemia, menstrual
cramps, treatment of skin lesions and difficult-to-heal wounds has not been scientifically confirmed [
9
].
In Indian Unani medicine, A. absinthium is the main ingredient in the drug “Afsanteen”, which is
used for chronic fever, hepatitis and oedema [
1
], while the traditional Chinese medicine (TCM) uses
A. absinthium in cancer therapy as a means of reducing angiogenesis [64].
6. Position in Modern Allopathy and Homeopathy
The pharmacopoeial raw material is the dried A. absinthium herb (Absinthii herba). According to
the latest editions (9th and 10th) of the European Pharmacopoeia and the 11th Polish Pharmacopoeia,
it is recommended to harvest the herb from young plants—in their first year of vegetation, basal leaves
are cut off, and from older plants—sparsely leaved, flowering shoot tips. One can also use a mixture
of them, as well as whole or broken-up fragments of the A. absinthium plant. The raw material is
standardized for essential oil content; in the dried herb, this content must not be less than 2 mL/kg [
12
].
In addition, the bitterness index of the raw material must not be less than 10,000 [12].
The herb of A. absinthium is used today mainly to improve digestion. The plant is part of the
pharmacopoeial (11th PF) Polish national herbal mixture Species digestivae together with Cichorii radix,
Angelicae archangelicae radix, Carvi fructus and Gentianae radix. The tincture of A. absinthium (Absinthii
tinctura) also has its pharmacopoeial monograph [65].
The raw material can also be found in other herbal mixtures recommended for hypoacidity,
digestive disorders, or lack of appetite. The remedy is mainly in the form of infusions recommended
for use before or during eating.
Since 1984, Absinthii herba has had a monograph in the German Pharmacopoeia. According to
the German guidelines, the raw material was recommended for loss of appetite, digestive problems,
and bile secretion disorders. It was recommended to use an infusion prepared from 1–1.5 g of dried
herb [
11
,
66
,
67
]. The daily dose should not exceed 2–3 g [
11
]. In addition, the German Pharmacopoeia
also mentioned a tincture from the herb [
68
]. However, Absinthii tinctura is not mentioned in the latest
(10th) edition of the European Pharmacopoeia [69].
According to ESCOP (European Scientific Cooperative on Phytotherapy), Absinthii herba may be
used in digestive disorders. Anorexia is also mentioned among the indications. ESCOP recommends
not to use the herb for a period longer than 3–4 weeks [30].
Absinthii herba has its monograph published by the European Medicines Agency (EMA), in which,
on the basis of well-established use, it is recommended to use the raw material in temporary loss of
appetite, mild dyspepsia, and in gastrointestinal disorders. The listed forms in which the raw material
can be used include finely divided or powdered herbal substance, fresh juice or tincture from the herb.
Commercial herbal preparations are made in solid or liquid forms, and finely divided herb is used in
herbal teas. All these forms are for oral use only. Contrary to the ESCOP recommendations, the EMA
specifies the maximum duration of use as 2 weeks [11].
The fresh, flowering herb of A. absinthium is classified in the European Pharmacopoeia and
the French Pharmacopoeia as a homeopathic raw material. The tincture produced should contain
a minimum of 0.05% w/wderivatives of hydroxycinnamic acid, expressed in terms of chlorogenic
Plants 2020,9, 1063 11 of 33
acid [
70
]. In homeopathy, the plant is recommended for hallucinations, nightmares, nervousness,
insomnia, dizziness, and epileptic seizures [71].
A. absinthium activity profiles documented in scientific papers, and the mechanisms of action of
the raw material, are presented below in the text and in Table 3.
Table 3. Pharmacological properties of A. absinthium.
Activity Mechanism of Action References
Stimulating digestion
•Change in postprandial haemodynamics in the gastric digestive phase with
increased hyperaemia, probably due to the effects of bitter compounds
contained in the herb of the plant.
[72]
Stimulating appetite
•
Enrichment of sheep fodder with silage containing A. absinthium increases the
amount of fodder consumed, improves digestion, induces nitrogen retention
and has a positive effect on the development of microorganisms involved in
nitrogen assimilation.
[73]
•Improvement in nutrient supply and digestion, faster growth, improvement
in carcass quality and amount of fatty acids among Hanwoo steers. [74]
Anthelmintic
•Extracts from A. absinthium cause paralysis and/or death of Haemonchus
contortus nematodes and reduce the number of the parasite’s eggs in the
host’s faeces.
[75]
•Lethal effect on Trichinella spiralis larvae. [19,76]
•Lethal effect of A. absinthium ethanolic extract on Ascaris suum eggs and
Trichostrongylus colubriformis larvae. [77]
•Lethal effect on Haemonchus contortus tested in vivo; reduction in its mobility
in vitro. [78]
Antiprotozoal
•Lethal effect of aqueous and ethanolic extracts from A. absinthium on
Plasmodium berghei.[79]
•Lethal effect of the essential oil on Plasmodium berghei. [80]
•Lethal effect of A. absinthium on Entamoeba histolytica. [81]
•Some lethal activity against Trypanosoma brucei.[82]
•
Lethal activity against the promastigota and amastigota forms of the protozoa
Leishmania aethiopica and Leishmania donovani.[83]
•Lethal activity in vitro against Leishmania infantum and Trypanosoma cruzi [24,34]
•Lethal effect of the essential oil on Trypanosoma cruzi and on Trichomonas
vaginalis. The compounds likely to be responsible for this activity are
(E)-caryophyllene and 3,6-dihydrochamazulene.
[26]
•Inhibition of Naegleria fowleri growth by sesquiterpenoid lactones in A.
absinthium.
[84]
•Lethal effect of A. absinthium aqueous extract against Plasmodium falciparum.[85]
AntibacterialAntifungal
•Growth inhibition by the essential oil from A. absinthium and its lethal
activity against: Escherichia coli, Pseudomonas aeruginosa, Klebsiella
pneumoniae, Staphylococcus sonnei, Staphylococcus aureus, Clostridium
perfringens, Listeria monocytogenes, Enterobacter aerogenes, Klebsiella
oxytoca, and Proteus mirabilis.
[20]
•Bactericidal activity of A. absinthium essential oil components against
Staphylococcus aureus.[86]
•Lethal effect of A. absinthium extract on Pseudomonas aeruginosa,
Haemophilus influenzae, Bacillus subtilis, Bacillus cereus, and
Staphylococcus aureus.
[87]
•Inhibition of growth of Fusarium oxysporum,Fusarium solani and Fusarium
moniliforme by the components of A. absinthium essential oil. [24]
•Inhibition of growth of Saccharomyces cerevisiae var. chevalieri and
Candida albicans. [18]
Plants 2020,9, 1063 12 of 33
Table 3. Cont.
Activity Mechanism of Action References
•Inhibition of growth of the bacteria Listeria monocytogenes and methicillin
sensitive/resistant Staphylococcus aureus, and the fungi Fusarium graminearum,
Fusarium culmorum,Fusarium oxysporum,Sclerotinia sp. and Rhizoctonia solani
by chamazulene in the essential oil.
[22]
•Some bactericidal activity of chlorogenic acid and efflux pump inhibition
(EPI) by 4,5-di-O-caffeoylquinic acid isolated from A. absinthium.[37]
•Lethal action against the fungi Alternaria alternata, Fusarium oxysporum,
Fusarium sambucinum, Fusarium solani and Aspergillus niger, and the
bacteria Arthrobacter spp., Bacillus mycoides, Micrococcus lylae,
Pseudomonas aeruginosa.
[88]
Anti-ulcer •Decrease in gastric juice volume, reduction in gastric acid and pepsin
secretion, and decrease in digestion rate. [89]
Hepatoprotective
•A. absinthium extracts inhibit liver microsomal enzymes that are responsible
for the metabolism of xenobiotics. [90]
•Methanolic extracts from the herb of the plant protect liver cells by reducing
ALAT and ASPAT levels, and by reducing oxidative damage. [91]
•Protection of the liver due to the immunomodulatory and/or antioxidant
properties of A. absinthium.[36]
Anti-inflammatory
•Reduction of inflammatory oedema in mice after administration of the
essential oil or methanolic extract from A. absinthium.[25,92]
•Inhibition of the expression of nitric oxide synthase and cyclooxygenase-2,
reduction in the production of prostaglandin E2, nitric oxide and tumour
necrosis factor (TNF-α), reduction in the accumulation of reactive oxygen
species by 5,6,30,50-tetramethoxy-7,4-hydroxyflavone isolated from A.
absinthium.
[42]
•Suppression of tumour necrosis factor (TNF-α) by compounds present in A.
absinthium. Among the compounds likely to be responsible for the
anti-inflammatory activity of the plant are the chalcone cardamonin,
flavonoids, artemisinin, and semisynthetic artesunate.
[38]
•
Cardamonin isolated from A. absinthium inhibits the NFkB pathway by direct
inhibition of DNA transcription factors, which leads to reduced NO release. [39]
•Reduction of paw oedema in rats given carrageenan and venom of
Montivipera xanthina after application of A. absinthium extract. [93]
Immuno-stimulating
•
Induction of dendritic cell maturation by increasing the level of CD40 surface
expression and by induction of cytokines. [94]
•Induction of TH1 immune response and stimulation of nitric oxide
production by macrophages. [43]
Cytotoxic •Inhibition of proliferation of breast cancer cells of MDA-MB-231 and
MCF-7 lines. [95]
•
The essential oil, in particular (E)-caryophyllene and/or germacrene D, is toxic
to tumour lines A548, NCI-H292, HCT116, MCF-7, SK-MEL-5. [37]
Analgesic •Reduction of temperature-induced pain in mice. [92]
•Reduction in episodes in the writhing test and delay in pain response in the
hot plate test in mice after administration of A. absinthium essential oil or
aqueous extract.
[25]
Neuroprotective
•Methanolic extract from A. absinthium, because of its antioxidant potential,
reduces brain damage, inhibits of lipid peroxidation, and restores the activity
of enzymes involved in reducing oxidative stress. Flavonoids and phenolic
acids in the plant are probably responsible.
[96]
•Protective effect of A. absinthium aqueous extract on glial cells and the
dopaminergic system when exposed to lead. [97]
•Caruifolin D in Absinthii herba inhibits the production of pro-inflammatory
microglia mediators and reactive oxygen species, and also inhibits protein C
kinase and stress-activated kinases.
[41]
Plants 2020,9, 1063 13 of 33
Table 3. Cont.
Activity Mechanism of Action References
Antidepressant •Shortening of the period of mouse immobility in the forced swim test and in
the tail suspension test. [98]
Procognitive •Affinity for human muscarinic and nicotinic receptors responsible for
cognitive functions. [99]
Neurotrophic •Methanolic, ethanolic and aqueous extracts from A. absinthium induce the
nerve growth factor (NGF), which stimulates development of neurites. [100]
Stabilizing cell
membranes
•Hydro-alcoholic extract from A. absinthium prevents haemolysis
of erythrocytes. [101]
Antioxidant
•Antioxidant activity of flavonoids and phenolic compounds in A. absinthium.[35]
•Reducing properties of polyphenols towards free radicals. [102]
•
A. absinthium contains active compounds that allow electron donation, which
prevents oxidation of structures by reactive oxygen species. [98]
•Synergistic antioxidant effects of the compounds present in the plant. [34]
•Methanolic extracts from A. absinthium herb have a significant
reduction potential. [22]
•A. absinthium essential oil has the ability to scavenge radicals in DPPH and
ABTS tests. [20]
•Reducing properties of A. absinthium extract and the ability to capture
superoxide and hydrogen peroxide anions, hydroxy and nitric oxide radicals;
inhibiting oxidative stress, reducing the concentration of TBARS, increasing
the concentration of superoxide and glutathione dismutases.
[103]
7. Biological Activities Confirmed by Scientific Research
7.1. Long-Known Possible Applications Confirmed by Modern Scientific Research
7.1.1. Effect of Stimulating Digestion
The bitterness-imparting compounds contained in wormwood herb enhance digestion through
various mechanisms. The first of these is irritation of the nerve endings on the tongue, which causes
reflex secretion of gastric juice. Another mechanism involves the stimulation of secretory nerves in
the liver and pancreas, as a result of which increased production of bile and pancreatic juice can be
observed. The bitter substances also have a direct effect on the stomach, leading to increased gastric
movements and enlargement of small vessels of the mucosa. It has been proved that the compounds
contained in the essential oil also increase the production of digestive juices and improve blood flow.
It is worth noting that the active compounds contained in Absinthii herba do not cause a significant
improvement in secretion in healthy people. The pharmacological effect is mainly observed among
patients with reduced digestive juice production.
A study attempted to confirm the mechanism responsible for the increased secretion of digestive
juices after the application of preparations containing A. absinthium. The experiment was conducted
with the participation of volunteers who received encapsulated cellulose water (control group) or
an ethanolic extract of A. absinthium herb (study group). The participants had their cardiovascular
parameters tested before and after ingestion. It was found that in the control group the strength of
heart contraction and arterial pressure increased, while among the study group given 1500 mg of
wormwood tincture, a decrease in peripheral vascular resistance and reduced cardiac output were
observed. In the control group, induction of gastric digestion occurred by increasing the strength of
heart contraction. By comparison, the consumption of bitter compounds induced the gastric phase by
increasing peripheral vascular resistance associated with the activation of the sympathetic nervous
system. A change in postprandial haemodynamics in the gastric phase of digestion along with
increased blood supply was reported as a likely mechanism for stimulating digestion [72].
Plants 2020,9, 1063 14 of 33
7.1.2. Anthelmintic Effect
A. absinthium has been proven to exert an anthelmintic effect against organisms such as: Trichinella
spiralis,Ascaris suum,Trichostrongylus colubriformis,Haemonchus contortus, as confirmed by the scientific
research outlined below.
One of the experiments examined the effects of A. absinthium on Trichinella spiralis (trichina worm).
Methanolic extracts from the herb of the plant were administered to rats suffering from trichinosis.
After sacrificing the rodents, samples of their muscles were subjected to trichinoscopic examination and
artificial digestion. Both methods determined the number of larvae in muscle tissue. Using 300 g/kg of
A. absinthium extract, the percentage of larvae during the intestinal phase of the disease decreased by
63.5% in the tongue, by 37.7% in the diaphragm, by 46.2% in the quadriceps muscles, and by 60.5% in
the biceps and triceps [76].
The same parasite was the object of further research. In the first of the experiments, A. absinthium
essential oil was applied to a suspension containing T. spiralis larvae, and after 24 h their infectivity
was checked by giving them to mice. Seven days after infection, the rodents were sacrificed and the
number of adult worms in the intestinal mucosa was counted. Using the essential oil at 1 mg/mL, up to
99.99% larvicidal effectiveness was achieved.
In another experiment, a group of mice were orally infected with T. spiralis larvae. A day later,
the animals were given A. absinthium essential oil. After 7 days, the animals were sacrificed and the
isolated small intestines were incubated to obtain adult forms of parasites and to count them. The best
nematocidal effect was observed at a dose of 500 mg/kg of body weight, at which the reduction in the
number of larvae was 66.07%. A positive control with albendazole showed a 65.97% reduction in the
number of larvae [19].
Another study tested the potential of an ethanolic extract from A. absinthium against the eggs
of Ascaris suum (porcine roundworm, parasite of pigs) and against the larvae of Trichostrongylus
colubriformis (parasite of rabbits). The extract showed significant lethal activity against both types of
parasites [77].
Another parasite that has attracted the attention of scientists is Haemonchus contortus. It is a
nematode whose hosts are ruminants. Most often, it infests sheep and goats, in which it causes anaemia,
which adversely affects the health of these farm animals [
104
]. In the search for new substances capable
of controlling infestations with this parasite, research has been carried out in many centres around the
world using extracts from A. absinthium.
One study evaluated the effectiveness of an aqueous and an ethanolic extract from A. absinthium
against H. contortus. The study involved a parasite motility inhibition test (
in vitro
), which demonstrated
the direct effect of the extracts on adult nematode individuals, and a test for reducing the number of
parasite eggs in host faeces (
in vivo
). In the motility test, both extracts showed a significant anthelmintic
effect, with the ethanolic extract being more effective than the aqueous one. In an
in vivo
study carried
out on sheep, the ethanolic extract on day 15 of the experiment showed a decrease in the number
of faecal eggs by 90.46% for a dose of 2 g/kg BW and 82.85% for a dose of 1 g/kg BW. The aqueous
extract proved to be less active also in this test. The maximum reduction in egg count of 80.49% was
observed at a dose of 2 g/kg BW. The likely reason for the greater activity of the ethanolic extract from
A. absinthium may be the better solubility in alcohol of the compounds responsible for the anthelmintic
effect [75].
Another study has also shown that aqueous and ethanolic extracts from A. absinthium (in an
in vitro
experiment) reduce the motility of H. contortus. An extract given to sheep for 8–10 days caused
complete expulsion of the parasite without visible toxicity in the animals [78].
In contrast to the positive results of the above experiments, one cannot overlook the study
conducted in 2011 in which an ethanolic extract from A. absinthium proved to be ineffective against the
same parasite. At a dose of 1000 mg/kg BW, no beneficial effect was observed in another animal model
(gerbils) [
105
]. Due to the conflicting results of the studies, further research is required on the impact
of A. absinthium extracts on H. contortus.
Plants 2020,9, 1063 15 of 33
7.2. New Possible Applications Substantiated by Scientific Research
7.2.1. Antiprotozoal Effect
Extracts from A. absinthium showed antiprotozoal activity against numerous pathogens:
Plasmodium berghei, P. falciparum, Naegleria fowleri, Trypanosoma brucei, T. cruzi, Leishmania
aethiopica, L. donovani, L. infantum, Trichomonas vaginalis, and Entamoeba histolytica.
One experiment (in 1990) examined the antimalarial effect of A. absinthium on an animal
model. Erythrocytes (1
×
10
7
) infected with Plasmodium berghei, the malaria-causing protozoan,
were intravenously administered to mice. After seven days, the rodents were given leaf extracts of
A. absinthium. The aqueous extract was given only orally, while the ethanolic extract was given orally,
subcutaneously, or intraperitoneally. All the extracts produced a reduction in parasitemia, but the best
inhibition effect of 96.2% was obtained with the ethanolic extract at a dose of 74 mg/kg. The results of
the study showed that preparations with A. absinthium could be an effective agent in the treatment of
malaria [79].
A further study conducted in 2010 confirmed also the antimalarial action of A. absinthium.
The
in vitro
study performed on chloroquine-resistant (K1) and chloroquine-sensitive (CY27) strains
of Plasmodium berghei grown with human erythrocytes showed that a hydro-ethanolic extract of
A. absinthium herb exhibited significant antimalarial activity. IC
50
values were determined after the
plant extracts had been administered by the lactate dehydrogenase method. They were 0.46
µ
g/mL for
the K1 strain and 0.195 µg/mL for the CY27 strain.
In a study
in vivo
, in turn, female BALB/c mice were injected with 1
×
10
7
erythrocytes infected
with Plasmodium berghei. On four consecutive days, the rodents were intravenously given 100 or
200 mg/kg A. absinthium herb extract. With the dose of 200 mg/kg, there was an 83.28% reduction in the
numbers of protozoa in the blood of the mice. The authors of the study indicated that the essential oil
may have been responsible for the antimalarial activity [80].
A different study tested the activity of A. absinthium against several pathogens that cause Chagas
disease, malaria, and leishmaniasis: Trypanosoma brucei and T. cruzi, Leishmania infantum and Plasmodium
falciparum, respectively. Various concentrations of A. absinthium herb extract were tested against these
protozoa. The extract showed low activity only against T. brucei [82].
Another protozoon against which the activity of extracts of the plant was checked is Naegleria fowleri.
It causes protozoal meningitis and encephalitis. The study checked the activity of an ethanolic and an
aqueous extract of A. absinthium, containing only the sesquiterpenoid lactone fraction. After applying
the diluted extracts onto a suspension of N. fowleri, even a 100% inhibition of protozoal growth was
observed, the effect being clearly dependent on the concentration [84].
In the next stage of the research, it was found that the aqueous extract of the herb of A. absinthium
showed a lethal effect on Plasmodium falciparum. Using a 35-fold diluted aqueous extract (1 g/mL), an
89.8% inhibition of protozoal growth was achieved [85].
Another study looked at the use of A. absinthium in leishmaniasis. The essential oil was isolated
from the plant and tested for its ability to control the protozoa—Leishmania aethiopica and L. donovani.
The results of the study showed an activity that inhibited the development of these microorganisms.
The minimal inhibitory concentration (MIC) for both microorganisms in the promastigote form was
0.1565
µ
L/mL, while for amphotericin B the value of MIC was 0.0244
µ
L/mL. The EC
50
(half maximal
effective concentration) value determined for the amastigote form was 42 nL/mL for L. donovani and
7.94 nL/mL for L. aethiopica, with amphotericin as the control, for which the EC
50
was 0.018
µ
L/mL
and 0.047
µ
L/mL, respectively. The results of the study may indicate that the compounds contained in
A. absinthium can be potential, effective agents for the treatment of leishmaniasis [83].
As part of subsequent, newer studies (2011), the use of A. absinthium in the treatment
of leishmaniasis caused by Leishmania infantum infection was also examined and, additionally,
the effectiveness of plant extract in the treatment of Chagas disease caused by Tripanosoma cruzi
was also investigated. The ED
50
value and the percentage of inhibition of protozoan growth after
Plants 2020,9, 1063 16 of 33
addition of A. absinthium extracts were tested. The tested extracts had a strong antiprotozoal effect.
To find the compounds responsible for this activity profile, the flavonoids—casticin and artemetin,
and the sesquiterpenoid lactone—hydroxypelenolide, were tested; unfortunately, none of the tested
compounds showed significant lethal effects [34].
These tests were continued by testing various concentrations of A. absinthium essential oil.
High mortality rates were found for both protozoa, reaching 96% for L. infantum and 99% for
T. cruzi [24].
Some other experiments focused on Trypanosoma cruzi and Trichomonas vaginalis (vaginal
trichomonad that causes trichomoniasis). The essential oil obtained from A. absinthium was divided into
nine fractions. All of the tested fractions showed lethal activity against both protozoa. After examining
the quantitative and qualitative compositions of the fractions showing the highest activity (fraction
VLC1 and VLC2), it was found that (E)-caryophyllene and 3,6-dihydrochamazulene may be responsible
for the antiprotozoal profile due to their high amounts in these fractions.
Further research into the antiprotozoal activity of A. absinthium is supported by the lack of
cytotoxicity towards healthy human cells, which has been confirmed in an
in vitro
study on the HS5
bone marrow stromal cell line [26].
Clinical studies have also been performed on the efficacy of A. absinthium in amoebiasis caused
by Entamoeba histolytica (amoeba that causes dysentery). Patients (numbering 25) with intestinal
amoebiasis were given a 500 mg capsule containing powdered A. absinthium herb three times a day for
15 weeks. The remedy brought relief to the patients at various stages of the disease, and complete
eradication was achieved in 70% of them [81].
7.2.2. Antimicrobial and Antifungal Activities
A. absinthium exhibits effective antifungal and antibacterial activities. Numerous studies have
shown the sensitivity of various microorganisms to the compounds contained in A. absinthium.
Among them are bacteria such as: Arthrobacter spp., Bacillus cereus,B. mycoides,B. subtilis,Clostridium
perfringens,Enterobacter aerogenes,Enterococcus faecalis,Escherichia coli,Haemophilus influenzae,Klebsiella
oxytoca,K. pneumoniae,Listeria monocytogenes,Micrococcus lylae,Proteus mirabilis,Pseudomonas aeruginosa,
Shigella sonnei,Staphylococcus aureus and the fungi: Aspergillus niger,Candida albicans,Fusarium culmorum,
F. graminearum,F. moniliforme,F. oxysporum fs. lycopersici,F. sambucinum,F. solani,Rhizoctonia solani,
Saccharomyces cerevisiae var. chevalieri,Sclerotinia sp. Extracts from the plant are particularly effective
against Gram-positive bacteria. Gram-negative bacteria have greater resistance, which is associated
with the presence of an outer phospholipid membrane that serves as an additional protective barrier of
these microorganisms [16].
One experiment tested the standard strains of Gram-negative bacteria: Escherichia coli,Pseudomonas
aeruginosa,Klebsiella pneumoniae,Shigella sonnei, and Gram-positive bacteria: S. aureus,Clostridium
perfringens,L. monocytogenes, and also bacterial strains isolated from patients’ stools or wounds
(E. coli,E. aerogenes,P. aeruginosa,K. oxytoca,P. mirabilis and S. aureus). In the experiment, after
adding A. absinthium essential oil to bacterial suspensions, the MIC and MBC (minimal bactericidal
concentration) were determined. The range of MIC values ranged from <0.08 mg/mL for P. mirabilis
and E. aerogenes isolated from stool and for P. aeruginosa and S. aureus isolated from wounds, up to
2.43 mg/mL for K. oxytoca isolated from stool. The MBC of essential oil ranged from 0.08 mg/mL against
E. aerogenes isolated from stool and S. aureus and K. oxytoca isolated from wounds, to 38.8 mg/mL
against L. monocytogenes. At a dose of approximately 40 mg/mL, the essential oil from A. absinthium
showed to be effective against all the bacteria tested
in vitro
. To be administered
in vivo
, this dose
would probably have to be much higher [20].
A. absinthium is a species that can probably be used also in patients with postoperative wound
infections caused by Staphylococcus aureus. This is indicated by the results of tests carried out on
rats that were cut on their back and the wound was infected with S. aureus. The wound was treated
topically with a hydro-alcoholic extract of A. absinthium herb. The number of bacteria in the test group
Plants 2020,9, 1063 17 of 33
was 3
×
10
5
cfu/wound, while in the control group 7
×
10
6
cfu/wound. The extract showed significant
bactericidal effectiveness, which the authors attribute to the compounds found in the essential oil of
the plant [86].
A subsequent study tested the effectiveness of a hydro-alcoholic extract from the herb of A.
absinthium against Pseudomonas aeruginosa, Haemophilus influenzae, Bacillus subtilis, B. cereus,
Klebsiella pneumoniae and Staphylococcus aureus. The experiment used the diffusion-disc method
and the parameter determined was the diameter of the growth inhibition zone. The A. absinthium
extract showed an activity against all the pathogens except K. pneumoniae. With a 750 mg/mL dose of
the extract, the inhibition zone was 11.9 mm for Pseudomonas aeruginosa, 18.4 mm for Haemophilus
influenzae, 14.4 mm for Bacillus subtilis, 20.4 mm for B. cereus, and 15.9 mm for Staphylococcus
aureus [87].
There has also been a study on the effect of A. absinthium on the fungi Fusarium moniliforme,
F. oxysporum fs. lycopersici and F. solani. Antifungal activity was determined by the diluted agar method
with the addition of 0.05 mg/mL methyltetrazolium salt. The percentage inhibition of colony growth
was adopted as the measured value. The tests involved checking the activity of essential oil derived
from cultivated A. absinthium plants, from wild plants in natural habitats, and from commercial oils.
The best activity was shown by a commercial oil and one of the cultivated populations. Seven of
the fifteen oils tested were active against F. oxysporum, six oils against F. solani, and only two against
F. moniliforme, below ED
50
=1
µ
g/mL. Authors claimed that the strongest effects were found for thujone
free cultivated A. absinthium plants [24].
As part of other experiments, the antimicrobial activity of oil from A. absinthium herb was tested
against Enterococcus hirae, Escherichia coli, Staphylococcus aureus, and against Candida albicans and
Saccharomyces cerevisiae var. chevalieri. The sensitivity of the pathogens was assessed by liquid diffusion.
The extract was antifungal towards both yeast species. The study did not prove antibacterial activity
against the bacteria used [18].
Still other experiments using the diffusion-disc method examined the activity of A. absinthium
essential oils against the bacteria: Staphylococcus aureus (strains sensitive and resistant to methicillin)
and Listeria monocytogenes, and the fungi: Fusarium graminearum, F. culmorum, F. oxysporum, Sclerotinia
sp. and Rhizoctonia solani. The essential oils tested in the experiment had been extracted from plants
harvested in various parts of Tunisia; however, the results showed that habitat location had no
influence on the effects produced by the oils. The strongest antibacterial activity was obtained against
a methicillin-sensitive strain of S. aureus, for which the diameter of growth inhibition was as large as 25
mm (inhibition zone for the positive control, tetracycline, was also 25 mm). For the methicillin-resistant
S. aureus, the largest inhibition zone was 16 mm, while for L. monocytogenes it was a maximum of 20 mm
(positive control—24 mm). In terms of antifungal activity, the oil was observed to have a significant
effect on F. graminearum, F. culmorum and F. oxysporum. The essential oil extracted from a plant collected
in the area of Jerissa (city located in the north-eastern part of Tunisia) proved to be additionally active
against Sclerotinia sp. and Rhizoctonia solani. The authors of the study attributed the antibacterial
and antifungal activities to the main component of the oil—chamazulene, but indicated that further
research was needed [22].
In recent years, the attention of scientists has been directed towards the search for new strategies
to overcome antibiotic resistance of individual strains of bacteria. One of the methods of increasing the
sensitivity to antibiotics is the simultaneous use of substances that inhibit the activity of membrane
efflux pumps (EPI—Efflux Pump Inhibitor). Such compounds prevent the removal of the drug from
inside the bacteria and increase the effectiveness of therapy [
89
]. In 2011, international studies were
conducted to determine the antimicrobial potential of A. absinthium, with particular emphasis on the
effect of caffeoylquinic acid derivatives on the ability to inhibit pump activity in Gram-positive bacteria.
Pathogens such as S. aureus,E. faecalis,E. coli and C. albicans were tested. The results revealed at least
two active compounds isolated from A. absinthium—chlorogenic acid, whose antimicrobial activity
was low, and 4,5-di-O-caffeoylquinic acid, which caused inhibition of pump activity in Gram-positive
Plants 2020,9, 1063 18 of 33
bacteria. The obtained data indicate that A. absinthium may be a source of substances capable of
reducing the antibiotic resistance of pathogens [37].
Similar studies have demonstrated the activity of A. absinthium essential oil against the bacteria:
Arthrobacter spp., Bacillus mycoides,Micrococcus lylae,Pseudomonas aeruginosa and against many species
of fungi. The studies provided evidence for the greatest inhibition of pump activity against: Alternaria
alternata,Fusarium oxysporum,F. sambucinum,F. solani and Aspergillus niger [88].
7.2.3. Anti-Ulcer Effect
One of the new directions of A. absinthium activity covered by research has been the anti-ulcer
activity, studied in laboratory animals. A group of rats were induced to develop ulcers using
acetylsalicylic acid. Extracts from the whole herb and roots of A. absinthium obtained using various
solvents (carbon tetrachloride, chloroform, methanol, ethanol, hexane) were administered to the
rodents both before and after they had received acetylsalicylic acid. The extracts from the plant did not
affect the activity of mucin; however, they caused a significant reduction in the volume of gastric juice,
a decrease in the secretion of gastric acid and pepsin, and a decrease in digestion rate [89].
7.2.4. Hepatoprotective Effect
Another new direction of A. absinthium activity studied has been the hepatoprotective activity.
Experiments were conducted to investigate the protective effect of a hydro-methanolic extract from
A. absinthium herb on hepatocytes in rats. Liver damage in the animals was caused by the administration
of acetaminophen (paracetamol) and carbon tetrachloride. After prophylactic two-day administration of
the plant extract at a dose of 500 mg/kg BW, reduced levels of asparagine and alanine aminotransferases
were found in the serum, in comparison with the control group. There was also a 20% reduction
in mortality due to acetaminophen administration. In the next stage of the study, A. absinthium
extracts were tested to verify if they could be used to reduce liver damage after administration of
acetaminophen and carbon tetrachloride. Acetaminophen-induced hepatotoxicity was significantly
reduced after three doses of extract at 500 mg/kg, but administering them did not affect carbon
tetrachloride-induced damage. Attempts were thus made to explain the hepatoprotective mechanism
of action of A. absinthium. To this end, the effect of the plant extract on the duration of sleep induced by
pentobarbital in mice and mortality induced by strychnine were investigated. Evidence was found of
sleep prolongation and increased mortality, suggesting inhibition of the activity of liver microsomal
enzymes [16,90].
In 2016, another experiment confirming the hepatoprotective effect of A. absinthium was conducted.
Twenty male rats, after being divided into four equal groups, received by gavage, respectively, a saline
solution, or 10, 50 or 100 mg/kg/day powdered methanolic extract from A. absinthium herb. Samples of
rodent blood were then taken and liver indicator levels compared with control samples (before using
the extract and saline solution). The best results were obtained for a dose of 50 mg/kg, at which a
significant decrease in the levels of alanine aminotransferase and asparagine aminotransferase was
found. Taking advantage of the capacity for reducing iron (II) ions, the antioxidant properties were
also measured, which increased significantly in rats receiving the extract at 50 mg/kg. The study thus
proved the hepatoprotective properties of wormwood extracts [91].
Evidence confirming the protective effect of A. absinthium on liver cells has been provided by
further experiments conducted on mice. In these laboratory animals, liver damage was induced by
administering carbon tetrachloride, or immunologically by injecting lipopolysaccharide. The rodents
were given an aqueous extract of A. absinthium. The results were very promising: significant reduction in
the levels of liver enzymes, inhibition of lipid peroxidation, and restoration of the activity of superoxide
dismutase (SOD) and glutathione peroxidase (GPx) in both chemically and immunologically induced
liver damage. In addition, a significant reduction in the number of pro-inflammatory mediators—TNF
α
and IL-1, was observed in the immunological model. Histopathological and other liver tests also
showed a reduction in the number of inflammatory cells [36].
Plants 2020,9, 1063 19 of 33
7.2.5. Anti-Inflammatory Effect
Another new direction of A. absinthium activities under investigation was the anti-inflammatory
activity. In one study, a methanolic extract from the herb of the plant was given orally to mice at doses
of 300 mg/kg, 500 mg/kg, and 1000 mg/kg. A positive control group received 300 mg/kg acetylsalicylic
acid, while a negative control group received a 0.9% sodium chloride solution. All of the mice were
then intravenously given carrageenan, which induced an inflammatory response. Anti-inflammatory
activity was estimated volumetrically by measuring rodent paw volume using a plethysmometer. There
was a 41% reduction in oedema volume, but it was short-lived, less intense and delayed compared
to the effect of acetylsalicylic acid. The authors of this work do not exclude that A. absinthium has a
significant anti-inflammatory effect; however, further studies are needed [92].
A similar study was conducted in 2014. During the similar experiment, mice were prophylactically
given A. absinthium essential oil at 2, 4, or 8 mg/kg, or an aqueous extract from the plant at 50, 100,
or 200 mg/kg; acetylsalicylic acid served as a positive control. Inflammation of rodent paws, as in
the previous study, was induced with carrageenan. The results showed that for the oil at 4 and
8 mg/kg there was a significant reduction in paw oedema, which indicated anti-inflammatory activity
of A. absinthium [25].
Researchers from four research centres were successful in isolating from A. absinthium the
flavonoid—5,6,3
0
,5
0
-tetramethoxy-7,4-hydroxyflavone (p7F), which was tested in
in vitro
and
in vivo
models for anti-inflammatory effects. The compound was tested for its effects on the production
of nitric oxide (NO), prostaglandin E2 (PGE2), tumour necrosis factor (TNF-
α
), as well as for the
expression of inducible nitric oxide synthase (iNOS), cyclooxygenase-2 (COX-2), and its effect on
collagen-induced arthritis. It was found that p7F inhibited the expression of iNOS and COX-2, and also
reduced the production of PGE2 and NO in lipopolysaccharide-stimulated cells of the RAW 264.7 line
(cell line of monocytes and macrophages). After administering p7F to the mice in which inflammation
had been induced by collagen, there was a decrease in the level of TNF-
α
and inhibition of the NF-
κ
B
pathway. The compound also prevented intracellular accumulation of reactive oxygen species. The
results suggest that p7F isolated from A. absinthium may find use in the treatment of inflammatory
diseases [42].
In 2010, a randomized clinical trial was conducted that examined the effect of A. absinthium extract
on the plasma level of tumour necrosis factor (TNF-
α
), which is a marker of ongoing inflammation
in the course of Crohn’s disease (ChL-C). Patients with ChL-C who were included in the study were
divided into two groups of ten. The control group continued standard therapy and received a placebo.
The study group, in addition to standard therapy, took orally 250 mg of dried, powdered A. absinthium
herb extract three times a day for six weeks. The absinthin content in a single dose was 0.32–0.38%.
The patients had their plasma TNF-
α
levels measured just before starting the treatment, then after three
weeks and after six weeks. In the study group, there was a decrease in TNF-
α
concentration from the
initial value of 24.5 pg/mL to 8.0 pg/mL after six weeks. In the control group, the value of 25.7 pg/mL
(week 0) dropped to 21.1 pg/mL (week 6). The change in Crohn’s Disease Activity Index (CDAI) was
also assessed and it was found to have decreased from 275 to 175 in the group of patients treated with
A. absinthium, and from 282 to 230 in the group receiving the placebo. Based on the conducted research,
it can be assumed that A. absinthium may be an effective plant in the treatment of inflammatory diseases
in which elevated TNF-αconcentration is observed [38].
Cardamonin—a chalcone isolated from A. absinthium, has been tested for its potential
anti-inflammatory activity. To this end, the effect of cardamonin on lipopolysaccharide-induced
release of nitrites and expression of iNOS and COX-2 proteins was assessed on two cell lines: THP-1
(monocyte cell line of acute monocytic leukaemia) and RAW 264.7 (cell line of mouse macrophages).
Using the western blot technique, the compound was also tested for its effect on phosphorylation of
mitogen-activated protein kinases (MAP): the ERK, JNK, and p38 MAP kinases, and on the activation
of the NFkB pathway. The results showed inhibition of NO release and inhibition of iNOS expression,
depending on cardamonin concentration, which led to the suppression of inflammation. The compound
Plants 2020,9, 1063 20 of 33
had no effect on the expression of COX-2, phosphorylation of MAP kinases, or phosphorylation of
NFkB. There was, however, inhibition of the NFkB pathway by direct inhibition of DNA transcription
factor. Induction of IFN-γactivated iNOS was also inhibited [39].
Another study examined whether A. absinthium would reduce inflammation induced with
carrageenan and the venom of Montivipera xanthina (Middle Eastern viper species) in rats. Half an
hour before the administration of venom or carrageenan, the rodents were intraperitoneally given
A. absinthium herb extract. The results indicated that administration of the plant extract at 25 and
50 mg/kg significantly inhibited venom-induced paw oedema, while doses of 12.5, 25 and 50 mg/kg
were effective in carrageenan-induced inflammation [93].
Anti-inflammatory activity can also be induced by caruifolin D contained in A. absinthium, which
has been proven in studies conducted in Beijing. This compound, by inhibiting the inflammatory
process, influenced the protection of nerve structures. The exact mechanism of action is described in
the sub-section “Neuroprotective effect” [41].
7.2.6. Immunomodulatory Effect
Extracts from Artemisia absinthium have also been the subject of research on their
immunomodulatory activity. One experiment examined whether A. absinthium extract had an
effect on the maturation of dendritic cells in laboratory mice. Dendritic cells were treated with an
ethanolic extract of A. absinthium herb for 18 h and then examined in a flow cytometer. The extract
was found to have a positive effect on dendritic cell maturation by increasing the level of surface
expression of CD40 protein, which acted as a marker co-stimulating dendritic cells and the induction
of cytokines. The study also assessed the degree of proliferation of allogeneic T-lymphocytes using
a mixed lymphocyte reaction (MLR) and enzyme-linked immunoassay (ELISA). During the MLR,
allogeneic T-lymphocytes were mixed with dendritic cells isolated from the mice treated with the A.
absinthium herb extract. It was found that at 100
µ
g/mL of extract the proliferation of T-lymphocytes
was reduced by 78.2% relative to the control. A significant increase in IL-10 levels was also observed.
The obtained results may serve to justify the traditional use of A. absinthium in immune disorders [
94
].
Another study proved that polysaccharides isolated from A. absinthium herb showed
immunostimulatory activity by inducing TH1 response and stimulating nitric oxide production
by mouse peritoneal macrophages [
50
]. Th1 helper lymphocytes, which support the body’s cellular
response, participate in TH1 response. Bactericidal macrophages and Tc-lymphocytes are activated,
and IgG class antibodies are produced, which activate the complement system. IL-2 interleukins and
interferon-
γ
are also produced [
106
]. The immune response elicited by polysaccharides isolated from
the herb of A. absinthium is particularly effective against intracellular viruses and bacteria [107].
7.2.7. Cytotoxic Effect
A. absinthium extracts have also been tested for anti-tumour activity. A methanolic extract from the
herb of the plant was used to treat breast cancer cells of the MDA-MB231 line (non-oestrogen-responsive
line) and MCF-7 breast adenocarcinoma cells (oestrogen-responsive line). After three days of exposure,
a 50% inhibition of MDA-MB231 cell proliferation at 20 g/mL and a 50% inhibition of MCF-7 cells
at 25 g/mL were demonstrated. Based on the results obtained, it was concluded that A. absinthium
might be a potential source of new compounds limiting the development of breast cancer and breast
adenocarcinoma [95].
The cytotoxicity of A. absinthium essential oil has also been tested.
In vitro
studies were performed
on six cell lines: A548 (lung adenocarcinoma cell line), NCI-H292 (non-small-cell lung cancer cell line),
HCT116 (colon cancer cell line), MCF-7 (breast adenocarcinoma cell line), SK-MEL-5 (melanoma cell
line), and HS5 (bone marrow stromal cell line—control). After multiplying the cells in the medium,
their reaction to A. absinthium essential oil and its individual fractions was examined. The tested
lines were found to be sensitive to the essential oil and/or its individual fractions in a dose-dependent
manner, with the best effect observed against the SK-MEL-5 and HCT116 lines, and the weakest against
Plants 2020,9, 1063 21 of 33
the MCF-7 line. The authors of the study associate the occurrence of the cytotoxic effect mainly with
the presence of (E)-caryophyllene and/or germacrene D because of the high concentration of these
compounds in the oil [26].
7.2.8. Analgesic Effect
As part of other experiments, in parallel with the testing of anti-inflammatory activity, as described
above, A. absinthium was also evaluated for its analgesic effect. The following scheme of the experiment
was used: the methanolic extract of the herb of the plant was administered orally to the mice in the
study group, at doses of 300 mg/kg, 500 mg/kg or 1000 mg/kg. A positive control group received
300 mg/kg acetylsalicylic acid, while a negative control group received a 0.9% sodium chloride solution.
The analgesic effect was assessed based on the delay in withdrawing the tail from water heated to
51
◦
C. A rapid onset of analgesic action was seen at all doses, but it was less pronounced compared to
that of acetylsalicylic acid. As in the study of anti-inflammatory activity, it was found that A. absinthium
could produce analgesic effects, but more experiments were required [92].
The analgesic properties of extracts from A. absinthium have been confirmed in the writhing test
and the hot plate test with mice in other studies. Before conducting the two tests, rodents were given
A. absinthium essential oil at doses of 2, 4, or 8 mg/kg, or an aqueous extract from the leaves of the
plant at doses of 50, 100, or 200 mg/kg. There was a significant reduction in writhing episodes in the
writhing test and a longer delay in pain response in the hot plate test compared to the control with
morphine, which may confirm the analgesic profile of A. absinthium [25].
7.2.9. Neuroprotective Effect
The neuroprotective potential of A. absinthium has also been assessed. To this end, an experiment
was designed in which obstruction of the middle cerebral artery in rats was caused with a nylon thread.
After 90 min, the thread was removed and the normal blood perfusion restored for 24 h. The temporary
closure of the middle cerebral artery led to infarction, lipid peroxidation, reduction in glutathione levels,
and a decrease in the activity of catalase and superoxide dismutase. There was a lack of locomotor
coordination and short-term memory impairment among the tested rats. An attempt was made to
reduce the losses by prophylactic oral administration of 100 mg/kg and 200 mg/kg methanolic extract
from the herb of A. absinthium. The results proved to be promising—there was evidence of a reduction
in oxidative stress, in the extent of brain damage, and in behavioural disorders, which indicates that
extracts from A. absinthium herb may be a potential agent in the prevention of stroke [96].
The results of another study indicate that the neuroprotective effect of A. absinthium may be
associated with the anti-inflammatory activity of the sesquiterpenoid dimer—caruifolin D, present in the
plant. In the experiment, this compound significantly inhibited the production of neuro-inflammatory
mediators in BV2 microglial cells. By inhibiting the production of reactive oxygen species, caruifolin
D also showed antioxidant activity; a decrease in protein kinase C and stress-activated kinases
(JNK) was also demonstrated. The authors of the study proved that caruifolin D in A. absinthium had
neuroprotective and anti-inflammatory potential. The researchers proposed this compound as potential
for use in the treatment of inflammatory neurological diseases such as Alzheimer’s or Parkinson’s [
41
].
Further studies assessed the role of A. absinthium aqueous extract in the neuroprotection of the
brain during prolonged exposure to lead. Among the group of rats that had been exposed to lead,
the number of dopaminergic neurons in the substantia nigra decreased by 50%, and the number of
astrocytes in the frontal cortex increased by 48%. It was proved that a four-week treatment of rodents
with an aqueous extract of A. absinthium at a dose of 200 mg/L reversed most of the lesions occurring in
glia and in the dopaminergic system [97].
One of the latest studies (2016) focused on the neuroprotective potential of A. absinthium herb
extracts in the oxidative stress caused by mercury. Damage in rat brains was induced by oral
administration of mercury (II) chloride (HgCl
2
) at a dose of 5 mg/kg. The rodents were then given
500 mg/L aqueous A. absinthium extract. A significant decrease in malondialdehyde (MDA) was
Plants 2020,9, 1063 22 of 33
recorded—by 26.99% in the cerebellum, by 31.81% in the cerebral cortex, and by 80.70% in the striatum;
induction of catalase activity in the cerebellum was also evident. The plant extract also restored the
activity of antioxidant enzymes—superoxide dismutase, glutathione peroxidase, glutathione reductase
and thioredoxin HgCl2reductase [108].
7.2.10. Antidepressant Effect
A. absinthium has also been tested as a plant with potential antidepressant activity. For this
purpose, the forced swim test and the tail suspension test were carried out on mice. In the first test,
125, 250, 500, or 1000 mg/kg methanolic extract of A. absinthium was injected intraperitoneally into
the mice from the study group. A positive control group received 5 or 10 mg/kg imipramine solution,
and a negative control group a 0.9% saline solution. The rodents were placed in a cylinder filled with
water and the duration of immobility was measured during the last four minutes of the experiment.
The A. absinthium extract significantly shortened the period of animal’s immobility compared to the
negative control group. The effect observed with an extract dose of 1000 mg/kg BW was comparable to
the effect after application of 5 mg/kg imipramine. The second test consisted in hanging the mouse
by its tail. After initial vigorous movements, periods of immobility during a five-minute observation
were recorded. The results of the second test showed that the A. absinthium extract significantly and in
a dose-dependent manner reduced the time of immobility of the mice, and that the effect caused by the
500 mg/kg dose of the extract represented the same antidepressant activity as that of imipramine [
98
].
7.2.11. Procognitive Activity
A study was conducted to check whether the historically known use of A. absinthium in the
treatment of memory disorders and reduced concentration was justified. Because it was known
that cholinergic receptors were involved in cognitive functions, the study examined the activity
of the binding of compounds extracted from A. absinthium to muscarinic and nicotinic receptors.
Ethanolic extracts from two batches of harvested plants were applied to the prepared homogenate of
human cortical brain cells; the ability to displace [3H]-(N)-nicotine and [3H]-(N)-scopolamine from
the receptors was determined. The results of the study showed that A. absinthium had significant
affinity for both muscarinic and nicotinic receptors, meaning that preparations from the plant can show
procognitive effects [99].
7.2.12. Neurotrophic Action
A study on the effects of A. absinthium herb extract on the nerve growth factor (NGF) in PC12D
cells (cell line of rat pheochromocytoma tumour) has also been conducted. Three types of extract
from the plant—methanolic, ethanolic, and aqueous, were tested. All of them showed neurotrophic
activity, increasing neurite development through NGF induction. The strongest effect was proven for
the methanolic extract, followed by the ethanolic one, while the aqueous extract produced a weak
effect. The obtained results indicate that extracts from A. absinthium herb may gain significance in the
treatment of neurodegenerative disorders [100].
7.2.13. Cell Membrane Stabilizing Effect
The protective effect of A. absinthium herb extracts on the haemolysis of human erythrocytes has
also been studied. Absorbance of a red blood cell solution with the addition of sodium chloride was
observed in the absence or presence of a crude aqueous extract of the A. absinthium herb. The extract
from the plant proved to be a good stabilizer of erythrocyte membranes, which can protect cells from
hypotonic shock [101].
Plants 2020,9, 1063 23 of 33
7.2.14. Antioxidant Effect
The herb of A. absinthium contains numerous flavonoids and other phenolic compounds that can
potentially determine its antioxidant activity.
In one experiment, the antioxidant activity of A. absinthium was tested using the DPPH method.
The plant material was extracted by successively using solvents of different polarity (70% methanol,
petroleum ether, chloroform, ethyl acetate, n-butanol). It was demonstrated that the antiradical activity
depended on the type of solvent and the concentration of extracts. The best results were obtained
using the acetate extract, then the extracts produced with methanol, n-butanol, chloroform, and ether.
The authors of the study concluded that the concentration of phenols and flavonoids influenced the
antioxidant activity of A. absinthium [102].
As part of another experiment, several tests were performed to test the activity of a methanolic
extract from A. absinthium herb. In the DPPH test, the IC
50
value for radical scavenging activity was
612
µ
g/mL. The IC
50
values for ascorbic acid, quercetin and butylated hydroxyanisole (BHA) used
as controls were 1.26
µ
g/mL, 1.32
µ
g/mL and 13.49
µ
g/mL, respectively. The methanolic extract from
A. absinthium also showed a reduction potential in the reaction with iron (III) ions, where the effect was
proven to depend on the concentration of the extract. Evidence was also found for a good capacity to
chelate iron(II) cations. The capacity for scavenging nitric oxide (NO) and hydrogen peroxide (H
2
O
2
)
was also tested. The IC
50
value for nitric oxide was 1.77 mg/mL and for quercetin (as a positive control)
the IC
50
value was 17.01
µ
g/mL. The A. absinthium extract also showed the ability to scavenge H
2
O
2
,
where the IC
50
value was 24.3
µ
g/mL, while for control samples with ascorbic acid and BHA these
values were IC
50
=21.4
µ
g/mL and IC
50
=52.0
µ
g/mL, respectively. Flavonoids (12.4 mg quercetin
equivalent/g extract) and phenolic compounds (194.9 mg gallic acid equivalent/g extract) were isolated
from the tested extract. The tests prove that the significant antioxidant activity of A. absinthium is
determined by the considerable concentrations of flavonoids and phenolic compounds [98].
A further study showed that extracts of A. absinthium herb from Spanish crops had a
stronger antioxidant effect in the DPPH test than the individually tested flavonoids—artemetin
and casticin, and the sesquiterpenoid lactone—hydroxypelenolide. In addition, the antioxidant effect
of hydroxypelenolide was stronger than that of the flavonoids tested. The results of the work suggest
that the antioxidant activity of A. absinthium is governed by the synergy of the compounds present in
the plant [34].
Antioxidative properties of methanolic extracts of A. absinthium herb were also tested using the
DPPH method with plants harvested from various regions of Tunisia. The results indicated that
the effectiveness of the antioxidant activity of the extracts was related to the location of the habitat
from which the plants were harvested. The strongest effect was found for extracts from the herb of
plants collected in the northern part of Tunisia (IC
50
=9.38 mg/mL). The second test method tested the
reduction potential for iron (III). Herb extracts were able to reduce iron(III) ions regardless of where
the plants had been harvested; moreover, the EC
50
values obtained were lower than for the ascorbic
acid control [22].
In another study using the DPPH and ABTS (2,2
0
-azino-bis(3-ethylbenzothiazoline-6-sulfonic
acid) methods, significant antioxidant properties of A. absinthium essential oil were found [20].
A subsequent study examined
in vitro
the activity of scavenging superoxide anions, hydrogen
peroxide, hydroxy radicals and nitric oxide, as well as the reduction potential of A. absinthium herb
extracts. In addition, an
in vivo
study was performed in which, after giving a methanolic extract of the
plant to mice, bilateral carotid artery occlusion was performed, reperfusion was restored, and then
the superoxide dismutase activity, concentration of thiobarbituric acid reactive substances (TBARS)
and glutathione content were determined by colorimetric methods. The results of the tests
in vitro
showed significant antioxidant activity in relation to all the compounds tested.
In vivo
, significant
inhibition of oxidative stress was found in the central nervous system after oral administration of 100 or
200 mg/kg of A. absinthium herb extract. The amount of TBARS also decreased and the concentrations
Plants 2020,9, 1063 24 of 33
of superoxide and glutathione dismutases increased, which indicates the possibility of using extracts
of the plant as an antioxidant [103].
In yet another study, the DPPH scavenging test was carried out on extracts from
in vitro
suspension
cultures of A. absinthium [
34
,
109
]. The highest antioxidant activity (82.7%) and maximum accumulation
of flavonoids (1.89 mg quercetin equivalent/g DW) and phenols (3.57 mg gallic acid equivalent/g DW)
were demonstrated for a 30-day suspension culture [35].
7.3. Importance in Veterinary Pharmacology
The herb of A. absinthium is characterized by a strong taste that can change the sensory experience
among animals consuming fodder. Adding the dried plant to the feed for ruminants has been found to
stimulate their appetite [73,109].
One of the experiments examined whether A. absinthium had a stimulating effect on appetite in
sheep. A flock of sheep (16 animals) was divided into four groups; in each of them the animals had a
different diet. The animals in the first group received 300 g/kg dry matter (DM) basic concentrates and
700 g/kg DM rice straw. In the second group, 50 g/kg DM straw was replaced with silage containing
A. absinthium; in the third group this was 100 g/kg DM, and in the fourth group 150 g/kg DM silage.
The results of the study showed that enriching the diet of sheep with A. absinthium-containing silage
significantly increased the amount of feed consumed. Improved digestion, increased nitrogen retention,
and an increase in the number of microorganisms involved in the assimilation of nitrogen were also
observed [73].
The effect of A. absinthium-containing silage on feed intake was also tested among Hanwoo
steers. The same research method was used and improvements in nutrient supply and digestion were
observed, as well as faster animal growth and improvements in carcass quality and the amount of fatty
acids [74].
8. Applications in Cosmetology
In addition to the undeniable therapeutic properties, A. absinthium has also found application in
cosmetics used for scalp, face, and hair care.
CosIng (Cosmetic Ingredient database)—a European database gathering data on cosmetic
ingredients, allows the use of Artemisia absinthium in five forms. Among them there are skin
care products, fragrances, and substances with antibacterial activity (Table 4) [110].
Table 4. Use of A. absinthium in cosmetology as recommended by CosIng database.
CosIng Data Description Functions
Artemisia absinthium extract •extract from the whole wormwood herb skin
conditioning
Artemisia absinthium herb extract •extract from the blooming herb of wormwood perfuming
Artemisia absinthium oil •volatile oil obtained from the whole
wormwood plant antimicrobial
Artemisia absinthium herb oil •essential oil obtained from the blooming
wormwood herb perfuming
Lactobacillus/Artemisia absinthium
leaf extract ferment filtrate
•
filtrate of the product obtained by fermentation
of wormwood leaves by bacteria of the genus
Lactobacillus
skin
conditioning
Raw materials obtained from the plant are used as components of cosmetic products such as
shampoos, face serums, masks, essences, tonics, moisturizing creams with an SPF filter, and under-eye
Plants 2020,9, 1063 25 of 33
patches. These forms of cosmetics are used to protect, cleanse, and moisturize the skin, as well as to
remove skin imperfections. They are produced mainly with extracts of the herb of the plant or distilled
oil; also included is the filtrate obtained after fermentation of the leaves by Lactobacillus sp.
Products containing A. absinthium can be found in the offers of foreign companies worldwide.
South Korean, Russian and American cosmetics producers are leaders among them.
9. Applications in the Food Industry
A. absinthium is the main ingredient in absinthe, which is a high-proof alcoholic beverage that was
particularly popular in the 19th and 20th centuries because of its psychoactive properties due to the
high
α
- and
β
-thujone content [
15
,
111
]. Information on the safety and mechanism of action of both
compounds is presented later in this review.
Dried aerial parts of the plant are used to produce absinthe. In a traditional recipe, wormwood,
along with other herbs, is macerated. The obtained macerate of a greenish colour with a slightly
stinging, strongly bitter taste is subjected to distillation, leading to a reduction in the amount of bitter
compounds. In the last stage, the distillate is diluted with water and the product has a characteristic
light green colour [15].
The European Food Safety Authority (EFSA) states that in the European Union, the
α
- and
β
-thujone content in alcoholic beverages, including absinthe, must not exceed 10 mg/kg for spirits with
an ethanol content higher than 25%, or it must not exceed 35 mg/kg in bitter spirits [112].
Wormwood is also added to wines to give them aroma and bitterness. Vermouths are a popular
type of wine containing A. absinthium. The whole herb together with A. absinthium roots is used for
their production; also used are other aromatic or bitter herbs (e.g., Salvia officinalis,Coriandrum sativum,
Citrus aurantium var. amara) and spices (e.g., Syzygium aromaticum,Cinnamomum zeylanicum,Zingiber
officinale). In the United States, vermouths are used to make cocktails, while in Europe they are served
without any admixtures [113].
In small quantities, A. absinthium is recommended for seasoning meat, vegetable soups and fresh
vegetables. It is also used as a dye and flavouring in the traditional Korean rice cake “green songpyeon”,
which is an integral part of the celebration of the “chuseok” thanksgiving festival. In Morocco,
A. absinthium is added to mint tea [31].
10. Safety of Use
It is worth pointing out the dangers of drinking absinthe. Its consumption initially causes the
feeling of well-being and hallucinations, slowly leading to a depressive stage. Chronic abuse of the
spirit has been described as absinthism, characterized by blindness, tremors, hallucinations, and
significant deterioration of the mental state. The degeneration that is observed in the advanced stage
causes convulsions and can even lead to death.
Currently, however, the influence of the substances present in A. absinthium herb on the
development of absinthism is being questioned. The most probable hypothesis is that absinthism is
misdiagnosed alcoholism because all the symptoms characteristic of absinthism can be attributed to
ethanol itself [114].
A. absinthium is a species rich in compounds that show toxic effects. These are
α
- and
β
-thujone,
with α-thujone being thought to be two to three times more harmful. The likely mechanism of action
of these compounds is interaction with the GABA receptor of chloride channels [
15
]. The compounds
exhibit neurotoxic activity leading to hyperactivity, tremors and tonic convulsions [
16
]. These symptoms
have been confirmed in studies on laboratory animals (mice). Intraperitoneal injection of
α
-thujone into
rodents induced tremors. Convulsions did not occur if diazepam or phenobarbital was administered
prophylactically [115].
EFSA emphasizes, however, that the
α
- and
β
-thujone content in the essential oil of the plant
ranges from 0% to 70.6%, which will also result in the occurrence or absence of side effects [31].
Plants 2020,9, 1063 26 of 33
Wormwood should not be used if the patient has gastric or duodenal ulcers, biliary obstruction,
liver disease, or if he is allergic to plants of the family Asteraceae. This species should not be used
during pregnancy and breastfeeding because, as shown in experiments on pregnant rats, Absinthii
herba hinders embryo implantation and reduces the number of births. An overdose of preparations
containing the plant may result in vomiting, diarrhoea and urinary retention [11,30].
The potential effect of skin irritation and potential acute toxicity of the essential oil of the plant
were investigated in 2014. After testing in healthy volunteers, researchers found no skin irritation
after applications of undiluted A. absinthium oil. Acute toxicity tests in a group of mice did not show
increased animal mortality after oral application of the essential oil; however, neurological, muscular
and gastrointestinal problems were observed [20].
As potentially dangerous compounds, EFSA lists
α
- and
β
-thujone, absinthin, and anabsinthin.
The summarizing conclusions regarding A. absinthium contain the information that the plant can be
safely used as a basic substance. It has a known toxicological profile, and the compounds that were
previously considered harmful are currently being investigated as medicinal substances [31].
The FDA (U.S. Food and Drug Administration) lists A. absinthium as an allergenic species.
The source of allergens is the pollen, which can also be present in extracts of the plant [116].
11. Biotechnological Research
Although there are no problems with obtaining A. absinthium fromnatural habitats or by cultivation,
attempts are being made at finding biotechnological solutions. They can undoubtedly bypass the
problems associated with the chemical variability of the raw materials derived from the plant—the
herb and the essential oil. Biotechnological research to date has been concerned with endogenous
production of secondary metabolites and the development of micropropagation protocols.
In 2013, one of Pakistani research groups proposed a method of producing A. absinthium secondary
metabolites by cultures
in vitro
. In the first stage aimed at establishing the cultures, they tested the
Murashige-Skoog (MS) medium enriched only with the addition of 0.5–5.0 mg/L thidiazuron (TDZ), or
a combination of TDZ with 1.0 mg/L naphthalene-1-acetic acid (NAA), or with 1.0 mg/L indole-3-acetic
acid (IAA). Thus prepared substrates were used to initiate cultures from leaf explants. Callus obtained
on MS media supplemented with 1.0 mg/L TDZ and 1.0 mg/L NAA was passaged for biomass growth.
Further experiments on the growth and production of secondary metabolites involved the use of
suspension cultures established from 35-day callus cultures. Biomass was grown in Erlenmeyer flasks
containing MS medium with 1.0 mg/L TDZ and 1.0 mg/L NAA. The biomass was taken for analysis at
3-day intervals during 42-day cultivation cycles. Phytochemical analysis was performed by HPLC.
Seedlings from germinating seeds constituted the control sample. The amount of phenolic acids in the
suspension was 3.57 mg/g (control: 2.75 mg/g), and the amount of flavonoid compounds was 1.77 mg/g
(control: 1.20 mg/g). The results of the study showed that A. absinthium suspension cultures might be a
good potential source of phenolic acids and flavonoids [35].
Scientists from the same research group also studied the effect of light and its absence on the
accumulation of secondary metabolites in A. absinthium suspension cultures. The cultures were grown
on MS medium supplemented with 1 mg/L TDZ and 1 mg/L NAA. The dynamics of biomass growth
were measured during 39-day cultivation cycles. Cultures grown in the presence of continuous artificial
light with a radiation intensity of 40 mol
·
m
−2·
s
−1
reached their maximum, 3.9-fold, increase in dry
biomass on day 30, whereas cultures grown in the dark, a 3.7-fold increase, on day 27 of cultivation.
In addition,
in vitro
cultures grown in the presence of light were found, using UV-VIS spectroscopy
methods with the addition of Folin-Ciocalteu reagent, to have elevated levels of phenols, while those
with the addition of aluminium chloride—elevated levels of flavonoids. The results of the study
showed that appropriate lighting conditions for A. absinthium cultivation had a positive effect on the
efficiency of secondary metabolite production [117].
A Hindu research group has developed a protocol for micropropagation of A. absinthium
by indirect organogenesis. The most effective for callus growth was MS medium with 0.5 mg/L
Plants 2020,9, 1063 27 of 33
2,4-dichlorophenoxyacetic acid (2,4-D) and 0.5 mg/L kinetin (Kin). Maximal induction of shoots from
callus was found on a medium containing 4.5 mg/L BAP (6-benzylaminopurine) and 0.5 mg/L NAA.
With a different quantitative combination of growth regulators, i.e., 1.5 mg/L BAP and 0.5 mg/L NAA, a
pronounced induction of many shoots from nodal explants was observed. The most beneficial medium
promoting rhizogenesis was one with the addition of 0.5 mg/L indole-3-butyric acid (IBA) [118].
12. Conclusions
A. absinthium is a species with a very important position in the history of Asian and European
medicine; described in medieval Europe as “the most important master against all exhaustions”, it was
mainly used to treat digestive tract diseases and worm infestations.
Nowadays, this species has the status of a pharmacopoeial species in the European allopathic as
well as homeopathic therapies. Currently the species occupies an important place in the traditional
European and Asian medicine.
In modern times, A. absinthium has been the object of numerous studies on the chemistry of raw
materials derived from it—the herb and the essential oil, as well as numerous studies on the biological
activity of extracts.
Research on the chemistry of the plant has identified a large number of compounds in the herb,
including most of all the presence of essential oil with a very rich but variable chemical composition,
bitter sesquiterpenoid lactones, flavonoids, other bitterness-imparting compounds, azulenes, phenolic
acids, tannins and lignans.
Research on biologically active extracts from the herb and/or individual isolated compounds and/or
essential oil has drawn attention to the mechanism of action of these raw materials in known classical
applications. It has also provided evidence for numerous, very valuable, previously unknown, new
directions of biological activity of the raw materials—antiprotozoal, antibacterial, antifungal, anti-ulcer,
hepatoprotective, anti-inflammatory, immunomodulatory, cytotoxic, analgesic, neuroprotective,
antidepressant, procognitive, neurotrophic, cell membrane stabilizing, and antioxidant effects.
Both phytochemical and pharmacological tests are carried out by research centres located all over
the world.
The species is also used with great success as a source of cosmetic raw materials, in Southeast
Asia, North America (USA) and Europe, in particular. The long-known significance of the species in
the food industry, as a base in the production of alcoholic beverages (absinthe and vermouth wines)
and as a valuable spice, is not decreasing. The species has also become the subject of biotechnological
research on the production of bioactive compounds and the possibility of micropropagation using
established in vitro cultures.
The proven new directions of the biological activity of extracts from the herb and of individual
isolated compounds and the essential oil of wormwood substantiate the medieval claim that Artemisia
absinthium is: “the most important master against all exhaustions”.
Author Contributions:
Data collection: H.E., J.P., P.K., A.R., A.S.; design of the study: H.E.; analysis and
interpretation of the data: H.E., J.P., P.K., A.R., A.S.; drafting the manuscript: H.E., J.P., A.S.; critical revision of the
manuscript: H.E., J.P., A.S.; contributed in writing and formatting the final version: A.S., H.O.E., F.A.A.-M. and
M.A.M. All authors have read and agreed to the published version of the manuscript.
Funding:
This work was supported by the Deanship of Scientific Research at King Saud University through
research group number RG-1440-12.
Acknowledgments:
The authors extend their appreciation to the Deanship of Scientific Research at King Saud
University (RG-1440-12).
Conflicts of Interest: All authors declare that they have no conflict of interest.
References
1.
Ahamad, J.; Mir, S.R.; Amin, S.A. Pharmacognostic review on Artemisia absinthium.Int. Res. J. Pharm.
2019
,
10, 25–31. [CrossRef]
Plants 2020,9, 1063 28 of 33
2.
Hussain, M.; Raja, N.I.; Akram, A.; Iftikhar, A.; Ashfaq, D.; Yasmeen, F.; Mazhar, R.; Imran, M.; Iqbal, M.A.
Status review on the pharmacological implications of Artemisia absinthium: A critically endangered plant.
Asian Pac. J. Trop. Dis. 2017,7, 185–192. [CrossRef]
3. The Plant List. Available online: http://www.theplantlist.org/(accessed on 12 March 2020).
4.
Hassler, M.; Roskov, Y.; Ower, G.; Orrell, T.; Nicolson, D.; Bailly, N.; Kirk, P.M.; Bourgoin, T.; DeWalt, R.E.;
Decock, W.; et al. World Plants: Synonymic Checklists of the Vascular Plants of the World (Version
November 2018). In Species 2000 & ITIS Catalogue of Life, 2019 Annual Checklist. 2019. Available online:
www.catalogueoflife.org/annual-checklist/2019 (accessed on 1 January 2020).
5.
Wikispecies, Free Species Directory. Available online: https://species.wikimedia.org/wiki/Main_Page
(accessed on 24 March 2020).
6. Khare, C.P. Indian Medicinal Plants: An Illustrated Dictionary; Springer: Berlin, Germany, 2007.
7.
Amidon, C.; Barnett, R.; Cathers, J.; Chambers, B.; Hamilton, L.; Kellett, A.; Kennel, E.; Montowski, J.;
Thomas, M.A.; Watson, B. Artemisia—An Essential Guide from the Herb Society of America; Caroline, A.,
Thomas, M., Kennel, E., Eds.; The Herb Society of America: Kirtland, OH, USA, 2014.
8.
Missouri Botanical Garden. Tropicos.org. Available online: http://www.tropicos.org/(accessed on 5 January
2020).
9.
Wichtl, M. Herbal Drugs and Phytopharmaceuticals: A Handbook for Practice on a Scientific Basis, 3rd ed.;
Medpharm: Marburg, Germany, 2004.
10. Van Wyk, B.E.; Wink, M. Medicinal Plants of the World; Timber Press: Portland, OR, USA, 2004.
11.
European Medicines Agency European Union. Herbal Monograph on Artemisia absinthium L. Herba.
Available online: https://www.ema.europa.eu/en/documents/herbal-monograph/final-european-union-
herbal-monograph-Artemisia-absinthium-l-herba-revision-1_en.pdf (accessed on 4 April 2020).
12.
Prezes Urz˛edu Rejestracji Produkt
ó
w Leczniczych Wyrob
ó
w Medycznych i Produkt
ó
w Biob
ó
jczych.
In Farmakopea Polska XI. Tom II.; Polskie Towarzystwo Farmaceutyczne: Warsaw, Poland, 2017.
13.
Hayat, M.Q.; Ashraf, M.; Ajab Khan, M.; Yasmin, G.; Shaheen, N.; Jabeen, S. Diversity of foliar trichomes and
their systematic implications in the genus Artemisia (Asteraceae). Int. J. Agric. Biol. 2009,11, 542–546.
14. GBIF.org. GBIF Home Page. 2020. Available online: https://www.gbif.org (accessed on 12 March 2020).
15.
Lachenmeier, D.W.; Walch, S.G.; Padosch, S.A.; Kröner, L.U. Absinthe—A review. Crit. Rev. Food Sci. Nutr.
2006,46, 365–377. [CrossRef]
16.
Beigh, Y.A.; Ganai, A.M. Potential of wormwood (Artemisia absinthium Linn.) herb for use as additive in
livestock feeding: A review. Pharma Innov. J. 2017,6, 176–187.
17. Geszprych, A. Diversity of wormwood (Artemisia absinthium L.) growing wild in Mazury area in respect of
the content and composition of the essential oil. Adv. Agric. Sci. Probl. Issues 2007,517, 317–324.
18.
Juteau, F.; Jerkovic, I.; Masotti, V.; Milos, M.; Mastelic, J.; Bessi
è
re, J.M.; Viano, J. Composition and antimicrobial
activity of the essential oil of Artemisia absinthium from Croatia and France. Planta Med.
2003
,69, 158–161.
[CrossRef]
19.
Garc
í
a-Rodr
í
guez, J.J.; Andr
é
s, M.F.; Ibañez-Escribano, A.; Julio, L.F.; Burillo, J.; Bol
á
s-Fern
á
ndez, F.;
Gonz
á
lez-Coloma, A. Selective nematocidal effects of essential oils from two cultivated Artemisia absinthium
populations. Zeitschrift für Naturforschung C 2015,70, 275–280. [CrossRef]
20.
Mihajilov-Krstev, T.; Jovanovi´c, B.; Jovi´c, J.; Ili´c, B.; Miladinovi´c, D.; Mateji´c, J.; Rajkovi´c, J.; Äorevi´c, L.;
Cvetkovi´c, V.; Zlatkovi´c, B. Antimicrobial, antioxidative, and insect repellent effects of Artemisia absinthium
essential oil. Planta Med. 2014,80, 1698–1705. [CrossRef]
21.
Bora, K.S.; Sharma, A. Phytochemical and pharmacological potential of Artemisia absinthium Linn. and
Artemisia asiatica Nakai: A Review. J. Pharm. Res. 2010,3, 325–328.
22.
Msaada, K.; Salem, N.; Bachrouch, O.; Bousselmi, S.; Tammar, S.; Alfaify, A.; Al Sane, K.; Ben Ammar, W.;
Azeiz, S.; Haj Brahim, A.; et al. Chemical composition and antioxidant and antimicrobial activities of
wormwood (Artemisia absinthium L.) essential oils and phenolics. J. Chem. 2015,2015. [CrossRef]
23.
Blagojevi´c, P.; Radulovi´c, N.; Pali´c, R.; Stojanovi´c, G. Chemical composition of the essential oils of Serbian
wild-growing Artemisia absinthium and Artemisia vulgaris.J. Agric. Food Chem.
2006
,54, 4780–4789. [CrossRef]
[PubMed]
24.
Bailen, M.; Julio, L.F.; Diaz, C.E.; Sanz, J.; Mart
í
nez-D
í
az, R.A.; Cabrera, R.; Burillo, J.; Gonzalez-Coloma, A.
Chemical composition and biological effects of essential oils from Artemisia absinthium L. cultivated under
different environmental conditions. Ind. Crop. Prod. 2013,49, 102–107. [CrossRef]
Plants 2020,9, 1063 29 of 33
25.
Hadi, A.; Hossein, N.; Shirin, P.; Najmeh, N.; Abolfazl, M. Anti-inflammatory and analgesic activities of
Artemisia absinthium and chemical composition of its essential oil. Int. J. Pharm. Sci. Rev. Res.
2014
,24,
237–244.
26.
Mart
í
nez-D
í
az, R.A.; Ib
á
ñez-Escribano, A.; Burillo, J.; de las Heras, L.; del Prado, G.; Agull
ó
-Ortuño, M.T.;
Julio, L.F.; Gonz
á
lez-Coloma, A. Trypanocidal, trichomonacidal and cytotoxic components of cultivated
Artemisia absinthium Linnaeus (Asteraceae) essential oil. Mem. Inst. Oswaldo Cruz.
2015
,110, 693–699.
[CrossRef] [PubMed]
27.
Obistioiu, D.; Cristina, R.T.; Schmerold, I.; Chizzola, R.; Stolze, K.; Nichita, I.; Chiurciu, V. Chemical
characterization by GC-MS and
in vitro
activity against Candida albicans of volatile fractions prepared from
Artemisia dracunculus,Artemisia abrotanum,Artemisia absinthium and Artemisia vulgaris.Chem. Cent. J.
2014
,8,
6. [CrossRef]
28.
Abad, M.J.; Bedoya, L.M.; Apaza, L.; Bermejo, P. The Artemisia, L. genus: A review of bioactive essential oils.
Molecules 2012,17, 2542–2566. [CrossRef]
29.
Joshi, R.K. Volatile composition and antimicrobial activity of the essential oil of Artemisia absinthium growing
in Western Ghats region of North West Karnataka, India. Pharm. Biol. 2013,51, 888–892. [CrossRef]
30.
European Scientific Cooperative on Phytotherapy. ESCOP Monographs: The Scientific Foundation for Herbal
Medicinal Products; Thieme: New York, NY, USA, 2003.
31.
European Food Safety Authority. Outcome of the consultation with Member States and EFSA on the
basic substance application for Artemisia absinthiumforuse in plant protection asfungicide in wheat and
asnematicide and insecticide in vegetables. Available online: https://efsa.onlinelibrary.wiley.com/doi/pdf/10.
2903/sp.efsa.2014.EN-665 (accessed on 19 August 2020).
32. Word, K. Homoditerpene peroxideds from Artemisia absinthium.Phytochemistry 1992,10, 340–342.
33.
Safayhi, H.; Sabieraj, J.; Sailer, E.; Ammon, H. Chamazulene: An antioxidant-type inhibitor of leukotriene B4
formation. Planta Med. 1994,60, 410–413. [CrossRef]
34.
Gonzalez-Coloma, A.; Bailen, M.; Diaz, C.E.; Fraga, B.M.; Mart
í
nez-D
í
az, R.; Zuñiga, G.E.; Contreras, R.A.;
Cabrera, R.; Burillo, J. Major components of Spanish cultivated Artemisia absinthium populations: Antifeedant,
antiparasitic, and antioxidant effects. Ind. Crop. Prod. 2012,37, 401–407. [CrossRef]
35.
Ali, M.; Abbasi, B.H. Ihsan-ul-haq. Production of commercially important secondary metabolites and
antioxidant activity in cell suspension cultures of Artemisia absinthium L. Ind. Crop. Prod.
2013
,49, 400–406.
[CrossRef]
36.
Amat, N.; Upur, H.; Blažekovi´c, B.
In vivo
hepatoprotective activity of the aqueous extract of Artemisia
absinthium L. against chemically and immunologically induced liver injuries in mice. J. Ethnopharmacol.
2010
,
131, 478–484. [CrossRef] [PubMed]
37.
Fiamegos, Y.C.; Kastritis, P.L.; Exarchou, V.; Han, H.; Bonvin, A.M.J.J.; Vervoort, J.; Lewis, K.; Hamblin, M.R.;
Tegos, G.P. Antimicrobial and efflux pump inhibitory activity of caffeoylquinic acids from Artemisia absinthium
against gram-positive pathogenic bacteria. PLoS ONE 2011,6, 1–12. [CrossRef] [PubMed]
38.
Krebs, S.; Omer, T.N.; Omer, B. Wormwood (Artemisia absinthium) suppresses tumour necrosis factor alpha
and accelerates healing in patients with Crohn’s disease—A controlled clinical trial. Phytomedicine
2010
,17,
305–309. [CrossRef]
39.
Hatziieremia, S.; Gray, A.I.; Ferro, V.A.; Paul, A.; Plevin, R. The effects of cardamonin on
lipopolysaccharide-induced inflammatory protein production and MAP kinase and NF
κ
B signalling pathways
in monocytes/macrophages. Br. J. Pharm. 2006,149, 188–198. [CrossRef]
40.
Javed, A.; Kamran, J.N.; Mohammed, A.; Showkat, R.M. New glycoside esters from the aerial parts of
Artemisia absinthium Linn. Nat. Prod. J. 2013,3, 260–267.
41.
Zeng, K.W.; Liao, L.X.; Song, X.M.; Lv, H.N.; Song, F.J.; Yu, Q.; Dong, X.; Jiang, Y.; Tu, P.F. Caruifolin D from
Artemisia absinthium L. inhibits neuroinflammation via reactive oxygen species-dependent c-jun N-terminal
kinase and protein kinase c/NF-κB signaling pathways. Eur. J. Pharmacol. 2015,767, 82–93. [CrossRef]
42.
Lee, H.G.; Kim, H.; Oh, W.K.; Yu, K.A.; Choe, Y.K.; Ahn, J.S.; Kim, D.S.; Kim, S.H.; Dinarello, C.A.; Kim, K.;
et al. Tetramethoxy hydroxyflavone p7F downregulates inflammatory mediators via the inhibition of nuclear
factor κB. Ann. N. Y. Acad. Sci. 2004,1030, 555–568. [CrossRef]
43.
Danilets, M.G.; Bel’ski
˘
ı, I.P.; Gur ’ev, A.M.; Belousov, M.V.; Bel’skaia, N.V.; Trofimova, E.S.; Uchasova, E.G.;
Alhmedzhanov, R.R.; Ligacheva, A.A.; Iusbov, M.S.; et al. Effect of plant polysaccharides on TH1-dependent
immune response: Screening investigation. Eksp. Klin. Farmakol. 2010,73, 19–22.
Plants 2020,9, 1063 30 of 33
44. Hegi, G. Illustrierte Flora von Mittel-Europa; Band VI/2.; J. F. Lehmanns Verlag: Munich, Germany, 1908.
45.
Unterkircher, F. Der Wiener Dioskoriodes: Codex Medicus Graecus 1 der ˝
Osterreichischen Nationalbibliothek Teil 1;
Mazal, O., Ed.; Akademische Druck u. Verlagsanstalt: Graz, Austria, 1998.
46.
Caius, P.S.K. Pliniusza Starszego Historyi Naturalnej Ksi ˛ag XXXVII; Ksi˛egarnia i drukarnia J. Łukaszewicza:
Poznan, Poland, 1845.
47.
Stoll, U. Das Lorscher Arzneibuch (Codex Bambergis Medicinalis 1); Franz Steiner Verlag: Stuttgart, Germany,
1992.
48. Pahlow, M. Das Grosse Buch der Heilpflanzen; Gräfe und Unzer Verlag: Augsburg, Germany, 2001.
49. Rätsch, C. Enzyklopädie der Psychoaktiven Pflanzen, 11 Auflage; AT Verlag: Aarau, Switzerland, 2013.
50. Dümmler, E. Poetae Latini medii aevi 2: Poetae Latini aevi Carolini (II); Weidmann: Berlin, Germany, 1884.
51.
Müller, I. Die Pflanzlichen Heilmittel bei Hildegard von Bingen/Heilwissen aus der Klostermedizin; Herder: Munich,
Germany, 2008.
52.
Lonitzer, A.; Uffenbach, P. Kräuter-Buch und Künstliche Conterfeyungen der Bäumen, Stauden, Hecken, Kräuter;
Verlag Bartholomae: Ulm, Germany, 1703.
53. Fuchs, L. Das Kräuterbuch von 1543; Taschen Verlag: Cologne, Germany, 2001.
54. Falimirz, S. O Ziołach i o Moczy Ich; Florian Ungler: Krakow, Poland, 1534.
55.
Urz˛edow, M. Herbarz Polski to jest o Przyrodzeniu Zi
ó
ł i Drzew Rozmaitych; Januszowski, Jan (1550–1613); Druk:
Krakow, Poland, 1595.
56.
Joannicy, G.; Makowski, T.; Skalski, B.; Syre´nski, S. Zielnik Herbarzem z I˛ezyka Łacinskiego Zowi ˛a; Drukarnia
Bazylego Skalskiego: Krakow, Poland, 1613.
57.
Tabernaemontanus, J.T. Neu Vollkommen Kräuterbuch/Mit Schönen und Künstlichen Figuren/Aller Gewächs
der Bäumen /Stauden und Kräutern/so in Denen Teutschen und Welschen Landen /Auch in Hispanien/Ost-und
West-Indien/Oder in der Neuen Welt. Gedruckt zu Basel/in Verl; Johann Ludwig König and Johann Brandmyller:
Basel, Switzerland, 1687.
58.
Zedler, J.H. Grosses Vollständiges Universal-Lexicon Aller Wissenschafften und Künste; Band 1.; Hrsg. v. Johann
Heinrich Zedler: Halle/Leipzig, Germany, 1732.
59. Roth, L.; Daunderer, M.; Kornmann, K. Giftpflanzen, Pflanzengifte; Nikol: Hamburg, Germany, 2012.
60.
Monographie BGA/BfArM Kommission, E. Bundesanzeiger 1984, Heftnummer, ATC-Code: A09A. Available
online: https://buecher.heilpflanzen-welt.de/BGA-Kommission-E-Monographien/(accessed on 19 August
2020).
61. Bäumler, S. Heilpflanzen Praxis Heute; Urban & Fischer: Munich, Germany, 2007.
62. Pi ˛atkowska, I. Lecznictwo ludowe w okolicach Sieradza. Wisła 1894,8, 138.
63.
Jastrz˛ebski, J. Tradycje Lecznictwa Ziołowego Zwierz ˛at/Historia Lek
ó
w Naturalnych. Vol. II, Natura i
Kultura—Wsp
ó
łzale˙zno´sci w Dziejach Lekoznawstwa; Ku´znicka, B., Ed.; Polska Akademia Nauk: Warszawa,
Poland, 1989; pp. 168–171.
64.
Parekh, H.S.; Liu, G.; Wei, M.Q. A new dawn for the use of traditional Chinese medicine in cancer therapy.
Mol. Cancer 2009,8, 1–8. [CrossRef] [PubMed]
65.
Prezes Urz˛edu Rejestracji Produkt
ó
w Leczniczych Wyrob
ó
w Medycznych i Produkt
ó
w Biob
ó
jczych.
In Farmakopea Polska XI. Tom III.; Polskie Towarzystwo Farmaceutyczne: Warsaw, Poland, 2017.
66.
Medizinprodukte, B. für A. In German Commission E Monograph; Blaumenthal, M.T., Hall, R., Rister, B., Eds.;
American Botanical Council: Austin, TX, USA, 1984.
67.
Medizinprodukte, B. für A. In German Commission D monograph; Blaumenthal, M.T., Hall, R., Rister, B., Eds.;
American Botanical Council: Austin, TX, USA, 1994.
68. German Pharmacopoeia; German Federal Institute for Drugs and Medical Devices: Bonn, Germany, 1872.
69.
Council of Europe. European Pharmacopoeia 10. Available online: https://www.edqm.eu/sites/default/files/
pheur_latin_index_10.0.pdf (accessed on 23 April 2020).
70.
Agence Nationale de S
é
curit
é
du M
é
dicament et des Produits de Sant
é
Absinthium for Homoeopathic
Preparations. Available online: https://www.ansm.sante.fr/var/ansm_site/storage/original/application/
27e6ac1e270d6995df0756d4fa0dc4ab.pdf (accessed on 17 April 2020).
71. Lockie, A. Encyclopedia of Homeopathy; DK Publishing: New York, NY, USA, 2006; ISBN 9780756618711.
72.
McMullen, M.K.; Whitehouse, J.M.; Whitton, P.A.; Towell, A. Bitter tastants alter gastric-phase postprandial
haemodynamics. J. Ethnopharmacol. 2014,154, 719–727. [CrossRef] [PubMed]
Plants 2020,9, 1063 31 of 33
73.
Kim, S.C.; Adesogan, A.T.; Kim, J.H.; Ko, Y.D. Influence of replacing rice straw with wormwood (Artemisia
montana) silage on feed intake, digestibility and ruminal fermentation characteristics of sheep. Anim. Feed
Sci. Technol. 2006,128, 1–13. [CrossRef]
74.
Kim, S.C.; Adesogan, A.T.; Shin, J.H. Effects of dietary addition of wormwood (Artemisia montana Pampan)
silage on growth performance, carcass characteristics, and muscle fatty acid profiles of beef cattle. Anim.
Feed Sci. Technol. 2012,177, 15–22. [CrossRef]
75.
Tariq, K.A.; Chishti, M.Z.; Ahmad, F.; Shawl, A.S. Anthelmintic activity of extracts of Artemisia absinthium
against ovine nematodes. Vet. Parasitol. 2009,160, 83–88. [CrossRef]
76.
Caner, A.; Dö¸skaya, M.; De
ˇ
girmenci, A.; Can, H.; Baykan, ¸S.; Üner, A.; Ba¸sdemir, G.; Zeybek, U.; Gürüz, Y.
Comparison of the effects of Artemisia vulgaris and Artemisia absinthium growing in western Anatolia against
trichinellosis (Trichinella spiralis) in rats. Exp. Parasitol. 2008,119, 173–179. [CrossRef]
77.
Urban, J.; Kokoska, L.; Langrova, I.; Matejkova, J.
In vitro
anthelmintic effects of medicinal plants used in
Czech Republic. Pharm. Biol. 2008,46, 808–813. [CrossRef]
78.
Singh, O.P.; Tiwari, S.K.; Ojha, D. Pilyriasis versicolor vis-a-vis sidhma and its ayurvedic management.
Sadvitra Ayurveda 1994,46, 920.
79.
Zafar, M.M.; Hamdard, M.E.; Hameed, A. Screening of Artemisia absinthium for antimalarial effects on
Plasmodium berghei in mice: A preliminary report. J. Ethnopharmacol. 1990,30, 223–226.
80.
Ramazani, A.; Sardari, S.; Zakeri, S.; Vaziri, B.
In vitro
antiplasmodial and phytochemical study of five
Artemisia species from Iran and
in vivo
activity of two species. Parasitol. Res.
2010
,107, 593–599. [CrossRef]
81.
Tahir, M.; Siddiqui, M.M.H.; Khan, A.B. Effect of Afsanteen (Artemisia absinthium Linn.) in acute intestinal
amoebiasis. Hamdard Med. 1997,40, 24–27.
82.
Vald
é
s, A.F.C.; Mart
í
nez, J.M.; Lizama, R.S.; Vermeersch, M.; Cos, P.; Maes, L.
In vitro
anti-microbial activity
of the Cuban medicinal plants Simarouba glauca DC, Melaleuca leucadendron L. and Artemisia absinthium L.
Mem. Inst. Oswaldo Cruz. 2008,103, 615–618. [CrossRef] [PubMed]
83.
Tariku, Y.; Hymete, A.; Hailu, A.; Rohloff, J.
In vitro
evaluation of antileishmanial activity and toxicity of
essential oils of Artemisia absinthium and Echinops kebericho.Chem. Biodivers. 2011,8, 614–623. [CrossRef]
84.
Mendiola, J.; Bosa, M.; Perez, N.; Hernandez, H.; Torre, D. Extracts of Artemisia abrotanum and Artemisia
absinthium inhibit growth of Naegleria fowleri
in vitro
.Trans. R. Soc. Trop. Med. Hyg.
1991
,85, 78–79.
[CrossRef]
85.
Hern
á
ndez, H.; Mendiola, J.; Torres, D.; Garrido, N.; P
é
rez, N. Effect of aqueous extracts of Artemisia on the
in vitro culture of Plasmodium falciparum.Fitoterapia 1990,41, 540–541.
86.
Moslemi, H.R.; Hoseinzadeh, H.; Badouei, M.A.; Kafshdouzan, K.; Fard, R.M.N. Antimicrobial activity
of Artemisia absinthium against surgical wounds infected by Staphylococcus aureus in a rat model. Indian J.
Microbiol. 2012,52, 601–604. [CrossRef]
87.
Habibipour, R.; Rajabi, M. Antibacterial effects of Arctium lappa and Artemisia absinthium extracts in laboratory
conditions. J. Herbmed Pharm. 2015,4, 133–137.
88.
Kordali, S.; Kotan, R.; Mavi, A.; Cakir, A.; Ala, A.; Yildirim, A. Determination of the chemical composition
and antioxidant activity of the essential oil of Artemisiadracunculus and of the antifungal and antibacterial
activities of turkish Artemisia absinthium,A. dracunculus,Artemisia santonicum, and Artemisia Spicig.J. Agric.
Food Chem. 2005,53, 9452–9458. [CrossRef]
89.
Shafi, N.; Khan, G.A.; Ghauri, E.G. Antiulcer effect of Artemisia absinthium L. in rats. Pak. J. Sci. Ind. Res.
2004,47, 130–134.
90.
Gilani, A.U.H.; Janbaz, K.H. Preventive and curative effects of Artemisia absinthium on acetaminophen and
CCl4-induced hepatotoxicity. Gen. Pharmacol. 1995,26, 309–315. [CrossRef]
91.
Mohammadian, A.; Moradkhani, S.; Ataei, S.; Shayesteh, T.H.; Sedaghat, M.; Kheiripour, N.; Ranjbar, A.
Antioxidative and hepatoprotective effects of hydroalcoholic extract of Artemisia absinthium L. in rat. J. Herbmed
Pharm. 2016,5, 29–32.
92.
Ahmad, F.; Khan, R.; Rasheed, S. Study of analgesic and anti-inflammatory activity from plant extracts of
Lactuca scariola and Artemisia absinthium.J. Islam. Acad. Sci. 1992,5, 111–114.
93.
Nalbantsoy, A.; Erel, ¸S.B.; Köksal, Ç.; Göçmen, B.; Yildiz, M.Z.; Karabay Yava¸so
ˆ
glu, N.Ü. Viper venom
induced inflammation with Montivipera xanthina (Gray, 1849) and the anti-snake venom activities of Artemisia
absinthium L. in rat. Toxicon 2013,65, 34–40. [CrossRef]
Plants 2020,9, 1063 32 of 33
94.
Shahnazi, M.; Azadmehr, A.; Hajiaghaee, R.; Mosalla, S.; Latifi, R. Effects of Artemisia absinthium L. extracts on
the maturation and function of dendritic cells. Jundishapur J. Nat. Pharm. Prod.
2015
,10, e20163. [CrossRef]
95.
Shafi, G.; Hasan, T.N.; Syed, N.A.; Al-Hazzani, A.A.; Alshatwi, A.A.; Jyothi, A.; Munshi, A. Artemisia
absinthium: A novel potential complementary and alternative medicine for breast cancer. Mol. Biol. Rep.
2012,39, 7373–7379. [CrossRef]
96.
Bora, K.S.; Sharma, A. Neuroprotective effect of Artemisia absinthium L. on focal ischemia and
reperfusion-induced cerebral injury. J. Ethnopharmacol. 2010,129, 403–409. [CrossRef]
97.
Sansar, W.; Gamrani, H. The pharmacological effect of Artemisia absinthium extract in protecting adult rats
against lead neurotoxicity. J. Neurol. Sci. 2013,333, e598. [CrossRef]
98.
Mahmoudi, M.; Ebrahimzadeh, M.A.; Ansaroudi, F.; Nabavi, S.F.; Nabavi, S.M. Antidepressant and
antioxidant activities of Artemisia absinthium L. at flowering stage. Afr. J. Biotechnol.
2009
,8, 7170–7175.
[CrossRef]
99.
Wake, G.; Court, J.; Pickering, A.; Lewis, R.; Wilkins, R.; Perry, E. CNS acetylcholine receptor activity in
European medicinal plants traditionally used to improve failing memory. J. Ethnopharmacol.
2000
,69, 105–114.
[CrossRef]
100.
Li, Y.; Ohizumi, Y. Search for constituents with neurotrophic factor-potentiating activity from the medicinal
plants of Paraguay and Thailand. J. Pharm. Soc. Jpn. 2004,124, 417–424. [CrossRef]
101.
De Freitas, M.V.; de C
á
ssia, M.; Netto, R.; da Costa Huss, J.C.; de Souza, T.M.T.; Costa, J.O.; Firmino, C.B.;
Penha-Silva, N. Influence of aqueous crude extracts of medicinal plants on the osmotic stability of human
erythrocytes. Toxicol. Vitr. 2008,22, 219–224. [CrossRef] [PubMed]
102.
Canadanovic-Brunet, J.M.; Djilas, S.M.; Cetkovic, G.S.; Tumbas, V.T. Free-radical scavenging activity of
wormwood (Artemisia absinthium L.) extracts. J. Sci. Food Agric. 2005,85, 265–272. [CrossRef]
103.
Bora, K.S.; Sharma, A. Evaluation of antioxidant and free-radical scavenging potential of Artemisia absinthium.
Pharm. Biol. 2011,49, 1216–1223. [CrossRef] [PubMed]
104.
Burke, J. Management of Barber Pole Worm in Sheep and Goats in the Southern U.S. Available online:
https://attra.ncat.org/downloads/goat_barber_pole.pdf (accessed on 7 April 2020).
105.
Squires, J.M.; Ferreira, J.F.S.; Lindsay, D.S.; Zajac, A.M. Effects of artemisinin and Artemisia extracts on
Haemonchus contortus in gerbils (Meriones unguiculatus).Vet. Parasitol.
2011
,175, 103–108. [CrossRef]
[PubMed]
106.
Eyerich, S.; Eyerich, K.; Pennino, D.; Carbone, T.; Nasorri, F.; Pallotta, S.; Cianfarani, F.; Odorisio, T.;
Traidl-Hoffmann, C.; Behrendt, H.; et al. Th22 cells represent a distinct human T cell subset involved in
epidermal immunity and remodeling. J. Clin. Investig. 2009,119, 3573–3585. [CrossRef] [PubMed]
107.
Spencer, L.A.; Weller, P.F. Eosinophils and Th2 immunity: Contemporary insights. Immunol. Cell Biol.
2010
,
88, 250–256. [CrossRef]
108.
Hallal, N.; Kharoubi, O.; Benyettou, I.; Tair, K.; Ozaslan, M.; Aoues, A.E.K.
In vivo
amelioration of oxidative
stress by Artemisia absinthium L. administration on mercuric chloride toxicity in brain regions. J. Biol. Sci.
2016,16, 167–177. [CrossRef]
109.
Kim, J.H.; Kim, C.H.; Ko, Y.D. Influence of dietary addition of dried wormwood (Artemisia sp.) on the
performance and carcass characteristics of Hanwoo steers and the nutrient digestibility of sheep. Asian
Australas. J. Anim. Sci. 2002,15, 549–554. [CrossRef]
110.
Cosmetics—CosIng. Available online: https://ec.europa.eu/growth/tools-databases/cosing/(accessed on
4 April 2020).
111.
Padosch, S.A.; Lachenmeier, D.W.; Kröner, L.U. Absinthism: A fictitious 19th century syndrome with present
impact. Subst. Abus. Treat. Prev. Policy 2006,1, 14. [CrossRef]
112.
European Commission Health and Consumer Protection Directorate-General. Opinion of the Scientific
Committee on Food on Thujone. Available online: https://ec.europa.eu/food/sites/food/files/safety/docs/fs_
food-improvement-agents_flavourings-out162.pdf (accessed on 4 April 2020).
113.
Panesar, P.S.; Kumar, N.; Marwaha, S.S.; Joshi, V.K. Review paper vermouth production technology—An
overview. Nat. Prod. Radiance 2009,8, 334–344.
114.
Lachenmeier, D.W. Wormwood (Artemisia absinthium L.)—A curious plant with both neurotoxic and
neuroprotective properties? J. Ethnopharmacol. 2010,131, 224–227. [CrossRef] [PubMed]
Plants 2020,9, 1063 33 of 33
115.
Höld, K.M.; Sirisoma, N.S.; Ikeda, T.; Narahashi, T.; Casida, J.E.
α
-Thujone (the active component of absinthe):
γ
-aminobutyric acid type A receptor modulation and metabolic detoxification. Proc. Natl. Acad. Sci. USA
2000,97, 3826–3831. [CrossRef] [PubMed]
116.
Food and Drug Administration. Pollens—Weeds and Garden Plants. Available online: https://www.fda.gov/
media/81288/download (accessed on 4 April 2020).
117.
Ali, M.; Abbasi, B.H. Light-induced fluctuations in biomass accumulation, secondary metabolites production
and antioxidant activity in cell suspension cultures of Artemisia absinthium L. J. Photochem. Photobiol. B Biol.
2014,140, 223–227. [CrossRef] [PubMed]
118.
Kour, B.; Kour, G.; Kaul, S.; Dhar, M.K.
In vitro
mass multiplication and assessment of genetic stability of
in vitro
raised Artemisia absinthium L. plants using ISSR and SSAP molecular markers. Adv. Bot.
2014
,2014,
1–7. [CrossRef]
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