Datura Species: Comparison
Please note this is a comparison between Version 1 by Prashant Kaushik and Version 2 by Vivi Li.

Datura, a genus of medicinal herb from the Solanaceae family, is credited with toxic as well as medicinal properties. The different plant parts of Datura sp., mainly D. stramonium L., commonly known as Datura or Jimson Weed, exhibit potent analgesic, antiviral, anti-diarrheal, and anti-inflammatory activities, owing to the wide range of bioactive constituents. With these pharmacological activities, D. stramonium is potentially used to treat numerous human diseases, including ulcers, inflammation, wounds, rheumatism, gout, bruises and swellings, sciatica, fever, toothache, asthma, and bronchitis. The primary phytochemicals investigation on plant extract of Datura showed alkaloids, carbohydrates, cardiac glycosides, tannins, flavonoids, amino acids, and phenolic compounds. It also contains toxic tropane alkaloids, including atropine, scopolamine, and hyoscamine. Although some studies on D. D. stramoniumstramonium have reported potential pharmacological effects, information about the toxicity remains almost uncertain. Moreover, the frequent abuse of D. stramonium for recreational purposes has led to toxic syndromes. Therefore, it becomes necessary to be aware of the toxic aspects and the potential risks accompanying its use.

  • Datura stramonium
  • alkaloids
  • atropine
  • cardiac glycosides
  • hyoscamine
  • Ayurveda

1. Introduction

Medicinal plants present a wide range of bioactive substances known for their pharmacological activities. In fact, the majority of conventional medicines rely on plant products. One such plant species is
Datura
spp., a flowering medicinal herb that pertains to the
Solanaceae
family [1], primarily used as an intoxicant and hallucinogen [2]. It is widely cultivated in Europe, Asia, America, South Africa, and other tropical and subtropical regions [3].
Datura can be well-grown in average soils, but it prefers nutrient-rich and moist soil or alkaline soil [4]. Although the plant acts as a narcotic, it has distinct effects on human health, rendering it incredibly beneficial as medicine [5][6]. This may be attributed to the fact that it possesses antimicrobial, antidiabetic, anti-asthmatic, anti-inflammatory, antioxidant, analgesic, insecticidal, cytotoxic, wound healing, and neurological activities [7][8]. The
can be well-grown in average soils, but it prefers nutrient-rich and moist soil or alkaline soil [4]. Although the plant acts as a narcotic, it has distinct effects on human health, rendering it incredibly beneficial as medicine [5,6]. This may be attributed to the fact that it possesses antimicrobial, antidiabetic, anti-asthmatic, anti-inflammatory, antioxidant, analgesic, insecticidal, cytotoxic, wound healing, and neurological activities [7,8]. The
Datura
plant is also known for its larvicidal effects against red flour beetle (
Tribolium castaneum) and mosquito repellent activities [9][10]. In addition,
) and mosquito repellent activities [9,10]. In addition,
Datura
spp. has also been used against animal bites such as snake bites, which helps relieve pain.
D. stramonium
, the well-known species of this family, is utilized for mystic and religious purposes along with its use as herbal medicine [11]. Moreover,
D. stramonium
seed is generally smoked to get a hallucinogenic experience [3].
The consumption of any part of
Datura plant may lead to the severe anticholinergic effect that may cause toxicity. In fact, the entire plant is toxic to some extent, but the seeds are found to be the most toxic; neither drying out nor boiling destroys the toxic properties [12][13]. Ayurvedic system of medicine has described
plant may lead to the severe anticholinergic effect that may cause toxicity. In fact, the entire plant is toxic to some extent, but the seeds are found to be the most toxic; neither drying out nor boiling destroys the toxic properties [12,13]. Ayurvedic system of medicine has described
D. stramonium as a valuable therapy for numerous human illnesses such as wounds, ulcers, rheumatism, fever, inflammation, asthma, and toothache [3][14]. A leaf extract taken orally can treat asthma along with sinus infection, and stripped bark can heal burns, swellings, and ulcers when applied externally to the affected area [9][15]. However, in the modern system of medicine, the therapeutic potentials of
as a valuable therapy for numerous human illnesses such as wounds, ulcers, rheumatism, fever, inflammation, asthma, and toothache [3,14]. A leaf extract taken orally can treat asthma along with sinus infection, and stripped bark can heal burns, swellings, and ulcers when applied externally to the affected area [9,15]. However, in the modern system of medicine, the therapeutic potentials of
D. stramonium
are dominated by its toxic effects. The intake of large doses of
D. stramonium
disturbs the central nervous system and produces symptoms like confusion, hallucinations and amnesia, and bizarre behavior [16]. In addition, the signs and symptoms of acute
D. stramonium poisoning include dryness of the lips and the epidermis, pupil dilation, urinary retention, impaired vision, and fast heartbeat [15][17].
poisoning include dryness of the lips and the epidermis, pupil dilation, urinary retention, impaired vision, and fast heartbeat [15,17].
Several incidences of accidental or intentional
D. stramonium
poisoning have been reported from different parts of the world, when eaten directly or through decoction made from herbal prescriptions, owing to its mind-affecting properties [18]. Therefore, the therapeutic applications require extensive research and analysis of the plant from every aspect, especially its toxicity. It should be consumed only with prior knowledge of its adverse effects since the consequences can be extremely harmful. With these facts, it is necessary to be aware of the toxic aspects and the potential risks accompanying its use.

2. Biochemical Composition of Datura

Datura
, in general, constitutes significant amounts of carbohydrates, fats, protein, moisture, ash content, and crude fiber. Besides, major phytochemicals found in
Datura include alkaloids, phenolic compounds, tannins, flavonoids, and cardiac glycosides [19][20]. In addition, many amino acids such as alanine, phenylalanine, glutamate, and tyrosine have also been isolated from the seeds [8].
include alkaloids, phenolic compounds, tannins, flavonoids, and cardiac glycosides [21,22]. In addition, many amino acids such as alanine, phenylalanine, glutamate, and tyrosine have also been isolated from the seeds [8].
Datura
species are particularly rich in tropane alkaloids. Hyoscine [(-)-Scopolamine] constitutes the major tropane alkaloid, along with hyoscyamine and atropine, having different concentration levels in different plant parts (
Figure 1) [11][21]. The atropine content in the leaves in
) [11,23]. The atropine content in the leaves in
Datura
metel
was found to be 0.426%, whereas hyoscyamine levels were found to be 0.426% in the seeds and 0.43% in flower [8]. The alkaloid contents of scopolamine and atropine in the entire plant in
D.
metel increase gradually with the development of various growth stages and becomes most apparent when the plant reaches the end of its reproductive stage [22][23]. However, in the case of
increase gradually with the development of various growth stages and becomes most apparent when the plant reaches the end of its reproductive stage [24,25]. However, in the case of
D. stramonium, the maximum amounts of alkaloids were found after ten weeks of seed germination, decreasing gradually with the beginning of the generative phase in plants [8][24]. Generally, the alkaloid concentration varies with the plant part and different growth stages in the plant. For example, leaves develop maximum alkaloid concentration in the vegetative phase, decreasing rapidly in the generative phase [25][26]. The stems and leaves of young plants contain hyoscyamine as a significant component. However, the concentrations of atropine and scopolamine differ in different plant parts in young and adult plants[9].
, the maximum amounts of alkaloids were found after ten weeks of seed germination, decreasing gradually with the beginning of the generative phase in plants [8,26]. Generally, the alkaloid concentration varies with the plant part and different growth stages in the plant. For example, leaves develop maximum alkaloid concentration in the vegetative phase, decreasing rapidly in the generative phase [27,28]. The stems and leaves of young plants contain hyoscyamine as a significant component. However, the concentrations of atropine and scopolamine differ in different plant parts in young and adult plants[9].
Figure 1.
Identified important phytochemicals in
Datura, as well as their chemical structures [27].
, as well as their chemical structures [30].

3. Pharmacological Activity of Datura

Datura
is known to exhibit analgesic, antioxidant, anticancer, and antimicrobial properties. Especially, owing to the potent analgesic activities,
D. metel
acts as an effective painkiller.
D. stramonium
has antifungal activity against
Fusarium mangiferae
and
Fusarium oxysporum
, alkaloids found in
D. stramonium are potential anticholinergic agents [28]. Atropine and scopolamine are muscarinic antagonists that may be utilized to cure Parkinson’s disease and parasympathetic stimulation of the eye, respiratory, urinary, heart, and gastrointestinal tract [29]. They prevent parasympathetic nerve impulses by selectively blocking the binding site of the neurotransmitter acetylcholine to the receptor of nerve cells [30]. In addition,
are potential anticholinergic agents [31]. Atropine and scopolamine are muscarinic antagonists that may be utilized to cure Parkinson’s disease and parasympathetic stimulation of the eye, respiratory, urinary, heart, and gastrointestinal tract [32]. They prevent parasympathetic nerve impulses by selectively blocking the binding site of the neurotransmitter acetylcholine to the receptor of nerve cells [33]. In addition,
Datura has long been utilized as a beneficial therapy for asthma symptoms. Atropine is the active anti-asthmatic agent that triggers paralysis of pulmonary branches of the lungs, removing the spasms responsible for the asthma attacks [31]. The technique of smoking
has long been utilized as a beneficial therapy for asthma symptoms. Atropine is the active anti-asthmatic agent that triggers paralysis of pulmonary branches of the lungs, removing the spasms responsible for the asthma attacks [34].
The technique of smoking
Datura
leaves through a pipe to alleviate allergies has its origins in the standard ayurvedic medicine in India.
D. stramonium
is utilized recreationally mainly for its anticholinergic consequences and can be produced by boiling the crushed seeds [13]. However, exposure of the fetus to
D. stramonium causes a continuous release of acetylcholine, leading to desensitization of nicotinic receptors, resulting in permanent damage to the fetus [3].

3.1. Anti-Inflammatory and Analgesic Activities

The phytochemicals present in
causes a continuous release of acetylcholine, leading to desensitization of nicotinic receptors, resulting in permanent damage to the fetus [3].

3.1. Anti-Inflammatory and Analgesic Activities

The phytochemicals present in
Datura species are well-known for their anti-inflammatory and analgesic properties due to their ability to suppress the production of chemical mediators responsible for the stimulation of nociceptors and induction of pain or inflammation [32][33]. The ethanolic extract of roots of
species are well-known for their anti-inflammatory and analgesic properties due to their ability to suppress the production of chemical mediators responsible for the stimulation of nociceptors and induction of pain or inflammation [35,36]. The ethanolic extract of roots of
D.
fastuosa was found to exhibit anti-inflammatory activity when studied for paw edema induced by carrageenan in rats, with Indomethacin as a standard drug [34][35]. The progress of edema can be explained in different phases; release of histamine and serotonin in the initial phase, edema maintained by substances like kinin in the plateau phase, and prostaglandin release in the edema accelerating phase [34][35]. The root extracts showed considerable activity against inflammation at 200 mg/kg compared to Indomethacin (at 10 mg/kg). Moreover, the aqueous extracts of seeds and leaves possessed significant analgesic effects at 800 and 400 mg/kg dosage, respectively, when experimented on mice using a writhing test (induced by acetic acid) and hot plate reaction [8]. However, the analgesic activity induced by leaves could be potentially decreased by naloxone, while that of seed extract remained unaffected. The aqueous leaf extracts of
was found to exhibit anti-inflammatory activity when studied for paw edema induced by carrageenan in rats, with Indomethacin as a standard drug [37,38]. The progress of edema can be explained in different phases; release of histamine and serotonin in the initial phase, edema maintained by substances like kinin in the plateau phase, and prostaglandin release in the edema accelerating phase [37,38]. The root extracts showed considerable activity against inflammation at 200 mg/kg compared to Indomethacin (at 10 mg/kg). Moreover, the aqueous extracts of seeds and leaves possessed significant analgesic effects at 800 and 400 mg/kg dosage, respectively, when experimented on mice using a writhing test (induced by acetic acid) and hot plate reaction [8]. However, the analgesic activity induced by leaves could be potentially decreased by naloxone, while that of seed extract remained unaffected. The aqueous leaf extracts of
D.
innoxia have been evaluated for their anti-inflammatory activity to develop an active herbal pain-relieving drug [36]. The basic mechanism involved in anti-inflammatory and analgesic action is believed to be the cyclooxygenase (COX1 and COX2) inhibition, followed by suppression of prostaglandin-synthesis or probably the narcotic effects of
have been evaluated for their anti-inflammatory activity to develop an active herbal pain-relieving drug [39]. The basic mechanism involved in anti-inflammatory and analgesic action is believed to be the cyclooxygenase (COX1 and COX2) inhibition, followed by suppression of prostaglandin-synthesis or probably the narcotic effects of
Datura species [33][36].

3.2. Antioxidation Activities

The antioxidant activity of
species [36,39].

3.2. Antioxidation Activities

The antioxidant activity of
Datura extracts can also be attributed to the presence of phytochemical compounds, which act as potent free radical scavengers and help prevent cellular damage [37]. Analysis of
extracts can also be attributed to the presence of phytochemical compounds, which act as potent free radical scavengers and help prevent cellular damage [40]. Analysis of
Datura plant extracts for antioxidant characteristics revealed its ability to cure various health disorders, including cancers, since antioxidants are known to inhibit cell damage, the general pathway for cancers, aging, and several other diseases [38]. The antioxidant capacity of leaf extracts in different solvents, estimated by various in vitro methods, including hydroxyl radical scavenging activity, DPPH (2,2-diphenyl-1-picrylhydrazyl) scavenging activity, superoxide radical scavenging activity, β-carotene bleaching activity, and reducing power assay, revealed that chloroform extract of leaves possessed maximum concentration-dependent antioxidant activity [39][40]. The IC
plant extracts for antioxidant characteristics revealed its ability to cure various health disorders, including cancers, since antioxidants are known to inhibit cell damage, the general pathway for cancers, aging, and several other diseases [41]. The antioxidant capacity of leaf extracts in different solvents, estimated by various in vitro methods, including hydroxyl radical scavenging activity, DPPH (2,2-diphenyl-1-picrylhydrazyl) scavenging activity, superoxide radical scavenging activity, β-carotene bleaching activity, and reducing power assay, revealed that chloroform extract of leaves possessed maximum concentration-dependent antioxidant activity [42,43]. The IC
50
value of methanolic and hydroalcoholic seed extracts of
D.
metel
recorded using the DPPH model showed that hydroalcoholic extract possesses slightly higher antioxidant activities (IC
50
of 25.78 µg/mL) than methanolic seed extract (IC
50 of 28.34 µg/mL) [7][39]. In the estimation of DPPH free radicals scavenging activities, a positive correlation was observed between the flavonoid and phenolic content of the
of 28.34 µg/mL) [7,42].
In the estimation of DPPH free radicals scavenging activities, a positive correlation was observed between the flavonoid and phenolic content of the
D.
metel extracts [8][39]. Maximum DPPH scavenging activity of methanolic seed extracts of
extracts [8,42]. Maximum DPPH scavenging activity of methanolic seed extracts of
D. stramonium
was found to be 59.50% at a concentration of 60 μg/mL with IC
50
value of 94.87 μg/mL; similarly, the maximum superoxide radical scavenging activity was 53.17% at a concentration of 60 μg/mL, while maximum scavenging activity of hydroxyl radical was 57.88% at concentration of 30 μg/mL with IC
50 value of 39.59 μg/mL [38]. Moreover, the hydromethanolic root extract of
value of 39.59 μg/mL [41]. Moreover, the hydromethanolic root extract of
D. stramonium exhibited a significant amount of correlation with DPPH free radical scavenging activity.

3.3. Antimicrobial Potential of Datura

The antimicrobial activity against pathogenic microbes was evaluated using aqueous and ethanolic extracts of different plant parts of
exhibited a significant amount of correlation with DPPH free radical scavenging activity.

3.3. Antimicrobial Potential of Datura

The antimicrobial activity against pathogenic microbes was evaluated using aqueous and ethanolic extracts of different plant parts of
D.
stramonium, and the results revealed that the ethanolic extracts showed better antimicrobial activity than the aqueous extracts [41][42]. Moreover, the leaf extracts were found to be more effective than stem and root. The branches and leaves of
, and the results revealed that the ethanolic extracts showed better antimicrobial activity than the aqueous extracts [44,45]. Moreover, the leaf extracts were found to be more effective than stem and root. The branches and leaves of
Datura
stramonium
extracted with different organic solvents such as benzene, chloroform, and ethanol exhibited significant antibacterial and antifungal activity when studied against
Enterobacter sp., Micrococcus luteus
,
Pseudomonas aeruginosa
,
Escherichia coli
,
Staphylococcus aureus,
and
Klebsiella pneumonia [8][43]. It was observed from the MBC (minimum bactericidal concentration) values that benzene extracts with the concentration of 3.12 mg/mL inhibited
[8,46]. It was observed from the MBC (minimum bactericidal concentration) values that benzene extracts with the concentration of 3.12 mg/mL inhibited
P. aeruginosa
while the chloroform extracted with the same concentration was effective against
S. aureus
,
P. aeruginosa,
and
M. luteus
. Further, all the
D.
stramonium
extracts were effective against various fungal strains such as
Aspergillus fumigatus
,
Aspergillus niger
, and
Saccharomyces cerevisiae
also, with maximum activity against
S. cerevisiae
and minimum antifungal activity against
A. niger
[8]. The methanolic and hydroalcoholic seed extracts of
D.
fastuosa
also possessed considerable antimicrobial properties against bacterial (
Bacillus subtilis, Escherichia coli, Staphylococcus aureus
) and fungal (
Aspergillus niger
and
Candida albicans) strains [8][44]. The methanolic extract acted against
) strains [8,20]. The methanolic extract acted against
E. coli
effectively with MBC of 25 µg/mL, while the hydroalcoholic extract was more effective against
B. subtilis
with both MBC and MIC (minimum inhibitory concentration) of 25 µg/mL. Methanolic plant extracts of
D. inoxia
also showed antifungal activity, and
Fusarium solani
was found more sensitive than other fungal species. The inhibition against different fungal species varied from 18.29 to 85.36%, where
F. solani
were affected more while
A. niger showed more resistance [45].
showed more resistance [47].
D. metel
seed oil had antibacterial activity against at least seven bacterial strains with the highest inhibition zone and lowest MIC against
Lactobacillus delbrueckii lactis
(19 mm) and
Pseudomonas aeruginosa
(18 mm), signifying susceptibility of bacterial strains to
D. metel seed oil. The antibacterial activity exhibited a concentration-dependent response, and the inhibition zone increased with an increase in seed oil concentration [46].

3.4. Anti-Asthmatic and Bronchodilating Effects

Alkaloids found in
seed oil. The antibacterial activity exhibited a concentration-dependent response, and the inhibition zone increased with an increase in seed oil concentration [48].

3.4. Anti-Asthmatic and Bronchodilating Effects

Alkaloids found in
D.
stramonium, such as atropine and scopolamine, which possess significant anticholinergic and bronchodilating activities, block the muscarinic receptors (which are important for airways regulation), subsequently dilating bronchial smooth muscles [47][48]. Acetylcholine (the neurotransmitter synthesized and released by cholinergic neurons) leads to the contraction of smooth muscle after interaction with cholinergic muscarinic Acetylcholine (Ach) receptors [49]. The muscarinic receptors associated with the airway and lung tissues are M1, M2, and M3, of which M1 and M3, fully active in asthmatics, are responsible for bronchoconstriction while M2 which suppresses the release of acetylcholine, are less functional in asthmatics [50].
such as atropine and scopolamine, which possess significant anticholinergic and bronchodilating activities, block the muscarinic receptors (which are important for airways regulation), subsequently dilating bronchial smooth muscles [49,50]. Acetylcholine (the neurotransmitter synthesized and released by cholinergic neurons) leads to the contraction of smooth muscle after interaction with cholinergic muscarinic Acetylcholine (Ach) receptors [51]. The muscarinic receptors associated with the airway and lung tissues are M1, M2, and M3, of which M1 and M3, fully active in asthmatics, are responsible for bronchoconstriction while M2 which suppresses the release of acetylcholine, are less functional in asthmatics [52].
Datura
administration inhibits M2 function, ultimately leading to the continued release of neurotransmitters. The anticholinergic activity of
D.
stramonium
involves blocking the functions of muscarinic receptors on airway smooth muscles and submucosal gland cells [14]. The anti-asthmatic
D. stramonium cigarette acts as a potential bronchodilator in asthmatic patients with the mild airway. A substantial decrease in the specific airway resistance (sRaw) was observed after inhaling smoke from the cigarette [8][51]. However, when exposed to the fetus during its use by the mother for asthma,
cigarette acts as a potential bronchodilator in asthmatic patients with the mild airway. A substantial decrease in the specific airway resistance (sRaw) was observed after inhaling smoke from the cigarette [8,53]. However, when exposed to the fetus during its use by the mother for asthma,
D. stramonium releases acetylcholine. It desensitizes nicotinic receptors, resulting in slow or no response to repetitive agonist modulatory effects on the brain’s functioning, consequently damaging the fetus [3][13].
releases acetylcholine. It desensitizes nicotinic receptors, resulting in slow or no response to repetitive agonist modulatory effects on the brain’s functioning, consequently damaging the fetus [3,13].
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