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Revista Brasileira de Farmacognosia 26 (2016) 128–133
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Review Article
Spilanthol: occurrence, extraction, chemistry and biological activities
Alan F. Barbosa a , Mário G. de Carvalho a , Robert E. Smith b,∗ , Armando U.O. Sabaa-Srur a,c
a
Departamento de Química, Instituto de Ciências Exatas, Universidade Federal Rural do Rio de Janeiro, Seropédica, RJ, Brazil
Park University, Parkville, MO, USA
c
Curso de Nutriçcão, Centro de Ciências da Saúde, Universidade Federal do Rio de Janeiro, Rio de Janeiro, RJ, Brazil
b
a r t i c l e
a b s t r a c t
i n f o
Article history:
Received 2 July 2015
Accepted 31 July 2015
Available online 9 September 2015
Spilanthol (C14 H23 NO, 221.339 g/mol) is a bioactive compound that is found in many different plants that
are used as traditional remedies throughout the world. It is present in Heliopsis longipes and several species
in the genus Acmella, including A. oleracea L., also known as paracress and jambu. Its leaves and flowers
have sensory properties (pungency, tingling, numbing, mouth-watering) that make it a popular spice and
ingredient in several Brazilian dishes. Spilanthol can exert a variety of biological and pharmacological
effects including analgesic, neuroprotective, antioxidant, antimutagenic, anti-cancer, anti-inflammatory,
antimicrobial, antilarvicidal and insecticidal activities. So, the aim of this review is to present a literature
review on the spilanthol that describes its occurrence, chemistry, extraction and biological activities.
Keywords:
Acmella oleracea
Alkamides
Bioactivity
Spilanthes oleracea L.
Heliopsis longipes
© 2015 Sociedade Brasileira de Farmacognosia. Published by Elsevier Editora Ltda. All rights reserved.
Introduction
Spilanthol (C14 H23 NO, 221.339 g/mol) (1) is a bioactive compound that is found in many different plants that are used as
traditional remedies throughout the world (Molinatorres et al.,
1996; Prachayasittukal et al., 2013; Paulraj et al., 2013; Rios
and Olivo, 2014). Its IUPAC name is (2E,6Z,8E)-N-isobutyl-2,6,8decatrienamide (Molinatorres et al., 1996). It is also known as
affinin (Prachayasittukal et al., 2013).
3'
6
2'
3'
N
1
2
4
1'
5
7
3
O
8
9
1
10
The plants in which it is found are often called toothache plants,
due to the analgesic effect of spilanthol (Molinatorres et al., 1996;
Hind and Biggs, 2003; Wu et al., 2008; Tiwari et al., 2011; Dias
et al., 2012; Sharma et al., 2012; Abeysiri et al., 2013; Dubey et al.,
2013; Prachayasittukal et al., 2013; Paulraj et al., 2013; Rios and
Corresponding author.
E-mail: robert.smith05@park.edu (R.E. Smith).
Olivo, 2014; Dandin et al., 2014; Hajdu, 2014). Like other alkamides,
it is an amphiphilic compound with a relatively polar amide and
a less polar fatty acyl. So, it can be extracted from plants using
either methanol, ethanol, supercritical CO2 or hexane (Nakatani
and Nagashima, 1992; Sharma et al., 2011; Dias et al., 2012; Singh
and Chaturvedi, 2012a,b; Hajdu, 2014; Abeysinghe et al., 2014).
After being extracted, it can be purified by preparative scale TLC
and/or HPLC (Johns et al., 1982; Ogura et al., 1982; Mbeunkui
et al., 2011; Pandey et al., 2011; Moreno et al., 2012; Nakatani
and Nagashima, 1992; Hajdu, 2014). In addition to its oral analgesic effect, it also has antibacterial effects (Dubey et al., 2013).
So, either spilanthol or extracts of plants that contain it may be
added to toothpaste and used as an oral analgesic in gels (such
as Buccaldol® and Indolphar® ) and as an anti-wrinkle cream that
can substitute for Botox in cosmetic applications (Demarne and
Passaro, 2009; Veryser et al., 2014). There are also some anti-aging
products (Gatuline® , SYN® -COLL, ChroNOlineTM ) that contain spilanthol. There are about 30 patents that describe products that are
made from a variety of Splianthes species (Haw and Keng, 2003).
It is also eaten in foods. The leaves of some of the plants (like S.
acmella) that contain spilanthol are used as a spice (Haw and Keng,
2003; Paulraj et al., 2013). The European Union estimated that the
average daily intake of spilanthol was 24 g/person/day (Veryser
et al., 2014). It is also possible that spilanthol, like other alkamides,
can have important effects on the central nervous system (CNS)
and immune system (Gertsch, 2008; Hajdu, 2014; Veryser et al.,
2014). However, its greatest potential for saving lives and improving human health may be its ability to kill mosquitoes that can
spread tropical diseases like malaria and dengue fever (Pandey
http://dx.doi.org/10.1016/j.bjp.2015.07.024
0102-695X/© 2015 Sociedade Brasileira de Farmacognosia. Published by Elsevier Editora Ltda. All rights reserved.
�A.F. Barbosa et al. / Revista Brasileira de Farmacognosia 26 (2016) 128–133
et al., 2011; Spelman et al., 2011; Hernández-Morales et al., 2015).
Moreover, it has anti-cancer activity (Soares et al., 2014; Mishra
et al., 2015). So, the purposes of this review are to tell where spilanthol (1) can be found in nature, tell how it can be extracted,
describe its chemistry and review its diverse health effects.
Occurrence
Spilanthol (or affinin) (1) can be found in not just Acmella oleracea, but also A. ciliate, A. oppositifolia, A. radicans, A. brachyglossa,
A. ciliate, A. oleracea, A. paniculata, A. uliginosa, Welelia parviceps
and Heliopsis longipes (Chung et al., 2008; Prachayasittukal et al.,
2013). Many of the articles that describe its presence in H. longipes
call it affinin instead of spilanthol (Johns et al., 1982; Rios et al.,
2007; Spelman et al., 2011; Déciga-Campos et al., 2012). On the
other hand, there is some disagreement in the literature over the
name of the genus and species of one of the most important plants
that is said to contain spilanthol. Some call it A. oleracea (Moreno
et al., 2012; Simas et al., 2013; Abeysinghe et al., 2014; Castro et al.,
2014), but others call it A. oleracea (L.) R. K. Jansen (Simas et al.,
2013; Soares et al., 2014; de Alcantara et al., 2014), A. oleracea Compositae (Hind and Biggs, 2003), S. oleracea L. (Martins et al., 2012), S.
acmella, (Chung et al., 2008; Demarne and Passaro, 2009; Mbeunkui
et al., 2011; Pandey et al., 2011; Prachayasittukal et al., 2013; Sana
et al., 2014; Soares et al., 2014; Mishra et al., 2015 S. acmella L.
var. oleracea Clarke (Nakatani and Nagashima, 1992) and S. acmella
Murr. (Asteraceae) (Singh and Chaturvedi, 2012a,b; Abeysiri et al.,
2013). At least one article stated that the flower head of S. acmella
L. var. oleracea Clarke are yellow, but those of S. acmella are purple (Nakatani and Nagashima, 1992). To add to the confusion, one
review article on the genus Spilanthes Jacq stated that “The genus
is often confused with the genus Acmella Rich. Ex Pers.”, “Spilanthes species have discoid heads and Acmella species have rayed
heads”, and “Spilanthes has a chromosome number of 16, whereas
Acmella has 12 or 13” (Paulraj et al., 2013). In complete contrast,
another author reported that the inflorescences of Acmella oleracea
(L.) R.K. Jansen have discoid heads and a chromosome number of
2n = 68 or 70 (Grubben and Denton, 2004). Monographs have been
written about each genus (Acmella and Spilanthes) (Jansen, 1981,
1985), but the “toothache plant” was placed in the Acmella genus
(Jansen, 1985). Some of its common names include jambu, agrião
do Pará and paracress (Jansen, 1985). The monograph on Acmella
warned of false synonyms for A. oleracea that appear on various
websites. Some of them state that the “accepted scientific name” is
Spilanthes acmella (L.) Murr., but the photos on them clearly show A.
oleracea (Jansen, 1985). This monograph also stated that the “currently accepted name” for Spilantes acmella (L.) Murr. is Blainvillea
acmella (L.) Philipson (Jansen, 1985). There is another article that
talks about a Mexican plant that they called Acmella (Spilanthes)
oppositifolia, while the Nahuatl name was chilcuage (Molinatorres
et al., 1996). There are also five different species of Acmella in Taiwan that contain spilanthol (Chung et al., 2008). Finally, there is
an article that lists S. acmella and S. oleraceae as being two separate
plants (Tiwari et al., 2011). Other synonyms include A. ciliata Kunth,
Cotula pyretharia L., S. fusca Mart, Bidens fervida Lan and A. uliginosa
(Sw.) Cass (Borges, 2009; Costa et al., 2013).
Extraction, purification and quantitation
Since spilanthol (1) is amphiphilic, it can be extracted from
plants using solvents that range in polarity from hexane (Ramsewak
et al., 1999) to methanol:H2 O (4:1, v/v) (Abeysinghe et al., 2014).
There is also an ethanolic extract that is sold in pharmacies (Boonen
et al., 2010a,b). However, to the best of our knowledge no attempt
has been made to compare the amount of spilanthol that can be
129
extracted using different methods. Moreover, nobody has ever tried
using pressurized liquid extraction with dry methanol, which has
been shown to be able to solubilize more material from many fruits
and vegetables than other methods, including Soxhlet extraction
or ultrasonication (Richter et al., 1996; Richards et al., 2014; Levine
et al., 2015). However, some of the previous publications do tell
how much material was solubilized. For example, hexane at an
unspecified temperature was able to solubilize 10 g of material
from 1130 g of lyophilized flowers (Ramsewak et al., 1999). Others used ultrasonication with 60 ml of ethanol:hexane (3:7, v/v) at
50 ◦ C and 30 min to solubilize an unspecified amount of material
from 2 g of dried flowers Costa et al., 2013). Another group used
an unknown amount of ethanol at room temperature to solubilize 106 g (13%) of material from 803 g of dried leaves (Simas et al.,
2013). Others solubilized 15 g from 300 g of flowers using methanol
at room temperature (Mbeunkui et al., 2011). Another group used
methanol to solubilize 18.0, 16.6 and 10.2% of the material from
dry leaves, stems and flowers, respectively (Abeysiri et al., 2013).
Still others used 2.5 l of ethanol:water (7:3, v/v) to solubilize an
unknown amount of material from 426 g of dried flowers (Martins
et al., 2012).
Supercritical CO2 with added ethanol and water was also used
to try to extract spilanthol from S. acmella flowers, leaves and stems
(Dias et al., 2012). It was purified from an ethanolic extract using
TLC using silica gel plates and hexane:ethyl acetate (2:1, v/v) as the
mobile phase (Dias et al., 2012). TLC was also used to purify spilanthol from dry A. oleracea flowers that was first extracted with
ultrasonication and ethanol:hexane (3:7, v/v) at 50 ◦ C and 30 min
(Costa et al., 2013). Others used TLC followed by preparative scale
HPLC to purify spilanthol from hexane extracts of flowers (Nakatani
and Nagashima, 1992). Another group used two preparative scale
columns (XAD-16 and Sephadex LH-20) followed by preparative
scale TLC to purify spilanthol from leaves (Simas et al., 2013).
Another approach that proved successful was column chromatography on silica gel, followed by TLC (Ramsewak et al., 1999). Finally,
centrifugal partition chromatography using a mixture of heptane,
ethyl acetate, methanol and water (3:2:3:2, v/v) was used to purify
spilanthol (Mbeunkui et al., 2011).
For quantitation, both HPLC with UV detection and LC–MS
have been used (Bae et al., 2010; Sharma et al., 2011; Singh and
Chaturvedi, 2012a,b). Both methods used a C18 column for the
separation. One HPLC method used an isocratic mobile phase consisting of 93:7 CH3 CN:H2 O (v/v), flowing at 0.5 ml/min (Singh
and Chaturvedi, 2012a,b). The retention time for spilanthol was
7.34 min (Prachayasittukal et al., 2013). Another HPLC method used
isocratic elution with CH3 CN:H2 O (1:1, v/v) flowing at 0.2 min (Bae
et al., 2010). The retention time was 4.97 min (Bae et al., 2010).
One LC–MS method used a gradient elution that started with 1:4
CH3 CN:H2 O (v/v), containing 1% acetic acid and increased to 9:1
CH3 CN:H2 O (v/v) over 150 min (Sharma et al., 2011). The retention time of spilanthol was 62.37 min (Sharma et al., 2011). The
other LC–MS method was validated for quantifying spilanthol in a
mixture of unspecified amounts of leaves, flower buds and roots,
which were extracted with ethanol:water (19:1, v/v) at room temperature (Bae et al., 2010). The combined peak areas due to the
[M+H]+ and [2M+H]+ ions with m/z of 222 and 443 were used for
quantitation (Bae et al., 2010). In addition, fragment ions with m/z
of 123, 81, 121, 67 and 149 were also seen. However, the method
was validated by simply analyzing spilanthol standards dissolved
in an unspecified solvent, showing that a linear calibration curve
could be obtained and by testing the repeatability of the analysis
of standards. Recoveries of spilanthol that were added to the samples (spiked samples) were not measured. It is also quite likely that
the method was not used to actually quantify spilanthol in any samples. There is a table that showed the spilanthol concentrations that
were found in extracts of the plant that they called S. acmella but
�130
A.F. Barbosa et al. / Revista Brasileira de Farmacognosia 26 (2016) 128–133
Table 1
1
H and 13 C NMR chemical shifts (ppm) of spilanthol (1) in CDCl3 (Nakatani and
Nagashima, 1992).
H no.
␦ 1 H (ppm)
C no.
␦ 13 C (ppm)
H-2
3
4
5
6
7
8
9
10
H-N
1�
2�
3�
5.79 br; d
6.83 dt
2.23–2.35 m
2.23–2.35 m
5.26 dt
5.97 dd
6.29 br; dd
5.70 dq
1.78 d
5.47 br, s
3.15 dd
C-1
2
3
4
5
6
7
8
9
10
1�
2�
3�
166.0
124.2
143.5
32.1
26.4
127.7
129.5
126.7
130.0
18.3
46.9
28.6
20.1
1.78 m
the results were expressed as mg/ml, as if they were concentrations of standards dissolved in solvents. There was no mention of
concentrations of spilanthol in units of g spilanthol per mg of sample (Bae et al., 2010). However, a method based on HPLC with UV
detection at 237 nm was used to find 3294 g/g spilanthol per dry
weight in the leaves of in vitro plants and 2704 g/g dry leaves in the
leaves of in vivo plants (Singh and Chaturvedi, 2012a,b). However,
no attempt was made to compare the amount of spilanthol that
could be extracted using pressurized liquid extraction, sonication
or Soxhlet extraction. It is also quite likely that the concentration
of spilanthol is different in different parts of the plant. So, there is
clearly a need for an analysis of different parts of genuine A. oleracea.
Chemistry
Spilanthol (1) is an N-alkylamide, many of which have various bioactivities, from helping to protect plants to being an
antibacterial, antifungal, analgesic and endocannabinoid agonists (Veryser et al., 2014). One article reported that there over
200 alkamides have been found in ten families: Aristolochiaceae, Asteraceae, Brassicaceae, Convolvulaceae, Euphorbiacea,
Menispermaceae, Piperaceae, Poaceae, Rutaceae and Solanaceae
(Molina-Torres et al., 2004). Another group reported that over 400
N-alkylamides have been identified in 26 different plant families
(Gertsch, 2008). There is also an alkamide database that has more
details in it (Boonen et al., 2012).
The stereoselective synthesis of spilanthol with a 61% yield has
been reported (Ikeda et al., 1984). It is light yellow with a melting
point of 23 ◦ C, a boiling point of 165 ◦ C, a refractive index at 298 ◦ C
of 1.5135 and a maximum UV absorption at 228.5 nm (Jacobson,
1957). Its IR spectrum was reported as having the following major
peaks: �max (film) cm−1 : 3340, 3150, 3080, 3020, 1678, 1636, 1550,
1240, 1160, 987, 953 (Nakatani and Nagashima, 1992). It has a
monoisotopic molecular weight of 221.177963 Da. So, the positive ion mass spectrum contains a molecular ion [M+H]+ m/z = 222
and a fragment [MH−C4 H11 N]+ with m/z = 149 (loss of isobutyl
amine group) as well as a fragment with m/z = 99, that showed
the presence of an isobutylamide (Jacobson, 1957). Its 1 H and 13 C
NMR spectra have been reported (Nakatani and Nagashima, 1992).
Chemical shifts are listed in Table 1.
The parts of spilanthol that are important for its analgesic activity, tingling and mouth-watering effects (pharmacophores) are the
amide and unsaturated (alkenyl) fatty acyl (Ley et al., 2006; Rios
and Olivo, 2014).
Biological activities
Spilanthol has many biological activities (Dubey et al., 2013),
including analgesic (Molinatorres et al., 1996; Hind and Biggs, 2003;
Wu et al., 2008; Cilia-López et al., 2010; Tiwari et al., 2011; Dias
et al., 2012; Sharma et al., 2012; Abeysiri et al., 2013; Dubey et al.,
2013; Prachayasittukal et al., 2013; Paulraj et al., 2013; Rios and
Olivo, 2014; Dandin et al., 2014; Hajdu, 2014 antinociceptive (Rios
et al., 2007; Déciga-Campos et al., 2012), antioxidant (Abeysiri et al.,
2013), anti-inflammatory (Wu et al., 2008; Hernández et al., 2009;
Dias et al., 2012), antimutagenic (Arriaga-Alba et al., 2013), antiwrinkle (Demarne and Passaro, 2009), antifungal (Dubey et al.,
2013), bacteriostatic (Molina-Torres et al., 2004), insecticidal (Kadir
et al., 1989; Sharma et al., 2012; Moreno et al., 2012), antimalarial (Sharma et al., 2012), anti-larvicidal activities against
Aedes aegypti and Helicoverpa zea neonates (Ramsewak et al., 1999),
and anti-molluscicidal activities (Johns et al., 1982). There have
also been reports on its activities as an anticonvulsant, antioxidant, aphrodisiac, pancreatic lipase inhibitor, antimicrobial agent,
antinociceptive agent, diuretic, vasorelaxant, anti-human immunodeficiency virus, toothache relief and as an anti-inflammatory
agent (Dubey et al., 2013). It can be absorbed through the skin,
endothelial gut, oral mucosa and blood–brain barrier (Boonen
et al., 2010a,b; Veryser et al., 2014). It can enhance the ability
of caffeine, fortestosterone and five mycotoxins to penetrate the
skin (De Spiegeleer et al., 2013). So, it is important to make sure
that formulations containing spilanthol are not contaminated with
mycotoxins (De Spiegeleer et al., 2013). It also improved male
sexual performance in rats as indicated by penile erection, mounting frequency, intromission frequency, ejaculation frequency that
lasted even 14 days after discontinuing its administration (Sharma
et al., 2011).
The antinociceptive activity of spilanthol was studied in detail
(Déciga-Campos et al., 2010). Intraperitoneal administration of
30 mg/kg spilanthol produced an antinociceptive dependent-dose
effect when assessed in mice submitted to acetic acid and
capsaicin tests. Spilanthol-induced antinociception was blocked
by naltrexone, p-chlorophenylalanine and flumazenil. So, its
antinociceptive effect may be due to the activation of opiodergic, serotoninergic and GABAergic systems. Moreover, the
antinociceptive effect decreased when mice were pretreated with
1H-[1,2,4]oxadiazolo[1,2-a]quinoxalin-1-one and glibenclamide.
This supports the idea that the nitric oxide-K+ channels pathway
could be involved in the mechanism of action (Déciga-Campos et al.,
2010). Subsequently, the same group found that spilanthol not only
had a antinociceptive effect, but it also modified anxiety behavior
and prolonged the time of sodium pentobarbital-induced hypnosis. They also found that spilanthol decreased the time of clonic
and tonic seizures that were induced by pentylenetetrazole (PTZ)
(Déciga-Campos et al., 2012).
Analgesic activity was studied by evaluating the inhibition of
acetic acid induced writhing in mice (Ogura et al., 1982). Spilanthol
was administered orally in aqueous solutions at doses ranging from
2.5 to 10.0 mg/kg. It exhibited an ED50 of 6.98 mg/kg. The analgesic
activity of spilanthol was attributed to increased GABA release in
the temporal cerebral cortex (Ogura et al., 1982). In another study,
spilanthol caused GABA to be released 0.5 min after being administered at a concentration of 1 × 10−4 M. One other study found that
spilanthol displayed analgesic action similar to ketorolac (CiliaLópez et al., 2010). Also, its stimulating effect on the nervous system
of adult mice was comparable to caffeine (Cilia-López et al., 2010).
The antimutagenic activity of spilanthol was demonstrated by
its ability to reduce 2AA- and NOR-induced mutations inTA98 and
TA102 strains of Salmonella Typhimurium (Arriaga-Alba et al., 2013).
Spilanthol (25 and 50 g/plate) significantly reduced the frameshift
mutations that were generated by 2-aminoanthracene (2AA) (40%)
and reduced the oxidative DNA damage generated by norfloxacin
(NOR) (37–50%) (Arriaga-Alba et al., 2013).
The antioxidant power of spilanthol and extracts of A. oleracea
have also been studied (Abeysiri et al., 2013). One study found 5.29,
�A.F. Barbosa et al. / Revista Brasileira de Farmacognosia 26 (2016) 128–133
1.42 and 3.42 mg of trolox equivalents per g of dry leaves, stems and
flowers (Abeysiri et al., 2013). It also found 7.59, 1.65 and 5.34 mg
of gallic acid equivalents per gram dry weight (mg GAE/g DW) of
total phenolic compounds (Abeysiri et al., 2013). A different study
found 9.2, 10.3 and 7.7 mg of trolox equivalents per g of dry arial
parts of A. oleracea grown three different ways: in the field, with
hydroponics and as a callus, respectively (Abeysinghe et al., 2014).
The same study found 11.0, 11.5 and 9.9 mg GAE/g DW total phenolics in A. oleracea grown in the field, with hydroponics and as
a callus, respectively (Abeysinghe et al., 2014). The total flavonoid
content was 11.3, 12.3 and 7.4 mg rutin equivalents per gram of dry
weight in A. oleracea grown in the field, with hydroponics and as a
callus, respectively.
The anti-inflammatory activity of dried flowers was demonstrated on the commonly used lipopolysaccharide-activated
murine macrophage model, RAW 264.7 (Wu et al., 2008). These
macrophages produce nitric oxide (NO) to mediate inflammation, through an inducible nitric oxide synthase (iNOS) and
cyclooxygenase-2 (COX-2). Spilanthol inhibited the production of
iNOS and COX-2 and the mRNA that code for them. It was also
suggested that spilanthol attenuates the inflammatory responses
in murine RAW 264.7 macrophages partly due to the inactivation
of NF-B. This down regulates the production of proinflammatory
mediators. Spilanthol also had an anti-inflammatory effect on the
arachidonic acid model with ED50 = 1.2 mg/ear (Wu et al., 2008). In
a different study using the phorbol myristate acetate model, spilanthol showed an anti-inflammatory dose-dependent effect with
ED50 = 1.3 mg/ear (Hernández et al., 2009).
Extracts containing spilanthol have been used to treat
toothaches, stomatitis and skin diseases such as swimmer’s
eczema (Boonen et al., 2010a,b). Extracts and spilanthol are
in buccal mucosa preparations that are indicated for a painful
mouth and minor mouth ulcers. Several spilanthol containing preparations for buccal use are commercially available
(Boonen et al., 2010a,b). Also, spilanthol has been incorporated
in tooth pastes and mouth rinses. The objective is to provide a lasting fresh minty flavor; it also increases salivation,
which improves appetite. The spilanthol present also has a mild
anesthetic effect thus enabling people with toothache to brush
comfortably (Hatasa and Iioka, 1973). There is also a patent
for manufacturing toothpastes or other oral compositions with
spilanthol-rich essential oils (Shimada and Gomi, 1995). A mouthwash contained ethanol 10.0, 85% glycerin 8.0, 65% sorbitol 2.0,
chlorohexidine gluconate 0.05, triclosan 0.003, menthol 0.01, peppermint oil 0.01, sodium saccharin 0.001, spilanthol-rich essential
oil 0.01 wt.% and balance purified water (Shimada and Gomi,
1995).
Also, spilanthol in A. oleracea L. extracts inhibited contractions in
subcutaneous muscles, notably those of the face, and can be used as
an anti-wrinkle product (Demarne and Passaro, 2009). As a result,
many anti-aging products containing spilanthol such as Gatuline® ,
SYN® -COLL and ChroNOlineTM are available.
The antifungal and bacteriostatic activities of spilanthol and
other alkamides from the roots of H. longipes were also studied
(Molina-Torres et al., 2004). Four of the assayed fungi showed
growth inhibition of 100% due to the presence of spilanthol: Sclerotium rolfsii, S. cepivorum, Phytophthora infestans, and Rhizoctonia
solani AG-3 and AG-5. Spilanthol also inhibited the growth of
Bacillus subtilis, Escherichia coli and Saccharomyces cerevisiae at concentrations as low as 25 g/ml (Molina-Torres et al., 2004). In
another study, spilanthol in S. calva was found to have antifungal activity against the fungi Fusarium oxysporum and Trichophyton
mentagrophytes (Rai et al., 2004). This antifungal activity was
enhanced when S. calva was inoculated with the root endophyte
Piriformospora indica, which also increased the concentration of
spilanthol in the roots of S. calva (Rai et al., 2004).
131
Spilanthol was also shown to be useful as an insecticide (Kadir
et al., 1989; Spelman et al., 2011; Sharma et al., 2012). It killed
the diamondback moth, Plutella xylostella L, which is one of the
most destructive pests that attack cruciferous vegetables, such
as broccoli (Sharma et al., 2012). Spilanthol was also able to
kill the tomato leafminer, Tuta absoluta (Meyrick) (Lepidoptera:
Gelechiidae), which attacks solanaceous plants and has become a
serious threat to tomatoes in the Mediterranean region (Moreno
et al., 2012). Electrophysiological studies indicated immediate
hyperexcitation followed by complete inhibition of the cockroach
cercal nerve activity. Spilanthol exhibited the highest toxicity to
Tuta absoluta, with the lowest LD50 (0.13 g mg−1 ). Furthermore,
spilanthol was approximately five times more toxic than permethrin and approximately 321 times more potent than Azadirachta
indica extract. On the other hand, spilanthol was not toxic to
two beneficial insects, the predator Solenopsis saevissima (Smith)
(Hymenoptera: Formicidae) and the pollinator, tetragonisca angustula (Latr.) (Hymenoptera: Apidae: Melipninae) (Moreno et al.,
2012). Even more important, spilanthol has been shown to be
toxic to the mosquitoes (Plasmodium falciparum) that carry malaria
(Spelman et al., 2011). It had an IC50 of 16.5 g/ml and 41.4 g/ml
on P. falciparum strain PFB and IC50 of 5.8 g/ml and 16.3 g/ml for
the chloroquine resistant P. falciparum K1 strain, respectively. Further investigations revealed that at relatively low concentrations,
spilanthol and the water extract of S. acmella reduced the parasitemia 59 and 53% in mice infected with P. yoelii yoelii 17XNL at 5
and 50 mg/kg, respectively. This parasite is used to infect mice in an
animal model of malaria. These results provide evidence supporting the antimalarial activities of S. acmella and spilanthol (Spelman
et al., 2011). Finally, another group reported the ability of extracts of
S. acmella Murr. to kill the American cockroach, Periplaneta americana L. (Kadir et al., 1989). The potency was found to be 1.3, 2.6
and 3.8 times more toxic than carbaryl, bioresmethrin and lindane,
respectively (Kadir et al., 1989).
Spilanthol is also active against Aedes aegyptii larvae, which
can spread the viruses that cause dengue fever, chikungunya, and
yellow fever as well as Helicoverpa zea neonates (corn earworm)
at concentrations of 12.5 and 250 mg/ml, respectively (Ramsewak
et al., 1999). Spilanthol, at 7.5 ppm concentration, caused 100%
motility of eggs, larvae, and pupae of Anopheles, Culex, and Aedes
mosquitoes at lower doses; it is also effective against eggs and
pupae (Saraf and Dixit, 2002). The insecticidal activity of Heliopsis longipes roots against Anopheles albimanus and Aedes aegypti
was determined (Hernández-Morales et al., 2015). A concentration of 7 mg/l of ethanolic extract caused 100% of larval mortality
for A. albimanus, and had the same effect on A. aegypti larvae.
This effect could be attributed to spilanthol. The conjugated double bonds present in its structure were found to be necessary to
maintain larvicidal activity. This study demonstrated the potential of H. longipes for controlling the larval stage of A. albimanus
and A. aegypti, transmitter vectors of malaria and dengue fever,
respectively (Hernández-Morales et al., 2015).
Others explored Spilanthes acmella Murr. for insecticidal activity (Sharma et al., 2012). The seed extract and spilanthol were
toxic to Plutella xylostella. An activity of 95–100% was observed
at a dose of 2 g/l of spilanthol, while 60–70 and 80–90% mortality was seen in crude seed extracts prepared in methanol and
hexane at a dose of 5 g/l after 48 h exposure. LC50 values of 1.49,
5.14, 5.04, 11.75 g/l were observed for spilanthol, crude methanolic
seed extract, hexane extracts and deltamethrin, respectively. These
findings indicated the potential of S. acmella and spilanthol for controlling P. xylostella and other insects of agricultural importance
(Sharma et al., 2012). Spilanthol also has strong molluscicidal activity against Physa occidentalis (LD50 of 100 M) and the cercariae of
the fluke (Johns et al., 1982). At a concentration of 50 mg/l in water
at 21◦ snails were inactive after 60 min and dead within 18 h. At
�132
A.F. Barbosa et al. / Revista Brasileira de Farmacognosia 26 (2016) 128–133
150 mg/l (the solubility limit for spilanthol) cercarial emergence
ceased and the snails showed immobility after 30 min. Cercariae
ceased to move after five set and convulsed after 1 min (Johns et al.,
1982).
Spilanthol also can also stimulate the growth of roots in Arabidopsis thaliana seedlings (Campos-Cuevas et al., 2008). Although
the effects of spilanthol was similar to those produced by auxins
on adventitious root development, the ability of shoot explants
to respond to spilanthol was found to be independent of auxin
signaling. These results suggest a role for spilanthol in regulating
adventitious root development, probably operating through the NO
signal transduction pathway (Campos-Cuevas et al., 2008).
Spilanthol was also shown to inhibit CYP P450 enzymes, with
IC50 values of 25, 16.1 and 13.5 g/ml for CYP1A1/2, CYP2D6 and
CYP3A4, respectively (Rodeiro et al., 2009). These results suggest
that spilanthol inhibits the major human P450 enzymes involved
in drug metabolism and could induce potential herbal–drug interactions (Smith, 2014). On the other hand, CYP1A1/2 inhibition
could be associated with decreased carcinogenic risk. Although,
in vitro inhibition of P450s does not necessarily lead to relevant
in vivo effects, these results recommend a cautious evaluation of
the potential clinical consequences derived from the consumption
of these products, particularly for long-term treatments (Rodeiro
et al., 2009).
In conclusion, spilanthol is a secondary metabolite with high
industrial potential as well as several biological properties and
health effects. It can be found, extracted and purified from A. oleracea and H. longipes. A. oleracea is used as a spice and a food in
the northern part of Brazil. It is also used as a treatment for treating toothaches, so it is called the toothache plant. Spilanthol may
also have analgesic (Molinatorres et al., 1996; Hind and Biggs,
2003; Cilia-López et al., 2010; Tiwari et al., 2011; Dias et al., 2012;
Sharma et al., 2012; Dubey et al., 2013; Prachayasittukal et al.,
2013; Paulraj et al., 2013; Wu et al., 2008; Rios and Olivo, 2014;
Dandin et al., 2014; Hajdu, 2014), antinociceptive (Rios et al., 2007;
Déciga-Campos et al., 2012), antioxidant (Abeysiri et al., 2013),
anti-inflammatory (Wu et al., 2008; Hernández et al., 2009; Dias
et al., 2012), antimutagenic (Arriaga-Alba et al., 2013), anti-wrinkle
(Demarne and Passaro, 2009), antifungal (Dubey et al., 2013), bacteriostatic (Molina-Torres et al., 2004), insecticidal (Kadir et al., 1989;
Box 1
Biological activities of spilanthol.
Biological activity
Reference
Analgesic
Antinociceptive
Antioxidant
Anti-inflammatory
Anti-wrinkle
Antifungal
Bacteriostatic
Insecticidal
Antimalarial
Anti-larvicidal against Aedes aegypti
and Helicoverpa zea neonates
Anti-molluscicidal
Anticonvulsant
Aphrodisiac
Pancreatic lipase inhibitor
Antimicrobial agent
Diuretic
Vasorelaxant
Anti-human immunodeficiency virus
Toothache relief
Enhance skin penetration of caffeine,
fortestosterone and five mycotoxins
Prachayasittukal et al. (2013)
Déciga-Campos et al. (2012)
Abeysiri et al. (2013)
Dias et al. (2012)
Demarne and Passaro (2009)
Dubey et al. (2013)
Molina-Torres et al. (2004)
Sharma et al. (2012)
Sharma et al. (2012)
Ramsewak et al. (1999)
Johns et al. (1982)
Dubey et al. (2013)
Dubey et al. (2013)
Dubey et al. (2013)
Dubey et al. (2013)
Dubey et al. (2013)
Dubey et al. (2013)
Dubey et al. (2013)
Dubey et al. (2013)
Dubey et al. (2013)
Sharma et al., 2012; Moreno et al., 2012), anti-malarial (Soares
et al., 2014), anti-larvicidal against Aedes aegypti and Helicoverpa
zea neonates (Ramsewak et al., 1999), and anti-molluscicidal (Johns
et al., 1982). There have also been reports on its activities as an anticonvulsant, antioxidant, aphrodisiac, pancreatic lipase inhibitor,
antimicrobial agent, antinociceptive agent, diuretic, vasorelaxant,
anti-human immunodeficiency virus, toothache relief and antiinflammatory (Dubey et al., 2013). The biological activities are listed
in Box 1.
However, the human toxicity of spilanthol has not been thoroughly tested, even though A. oleracea and H. longipes have been
consumed for a long time. Also, the concentrations of spilanthol in
different parts of these plants have not been determined.
Authors’ contributions
AFB, MGC, RES and AUOSR all contributed to the concept, literature search and writing of this review article.
Conflicts of interest
The authors declare no conflicts of interest.
Acknowledgements
The authors want to thank the Fundaçcão Carlos Chagas de Apoio
a Pesquisa do Estado do Rio de Janeiro (FAPERJ), CNPq, and to CAPES
for scholarships and financial support.
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