- Research article
- Open Access
- Open Peer Review
Anti-inflammatory, antioxidant, and antimicrobial activities of Cocos nucifera var. typica
© Silva et al.; licensee BioMed Central Ltd. 2013
- Received: 1 November 2012
- Accepted: 8 May 2013
- Published: 16 May 2013
Teas from the husk fiber of Cocos nucifera are used in the folk medicine to treat arthritis and other inflammatory processes. Some works show that some varieties have biological activities. However, one of the main variety of the species, C. nucifera var. typica, known in Brazil as “gigante”, was not studied yet. Thus, this study evaluates if this variety has the anti-inflammatory and antimicrobial activities already reported in other varieties.
C. nucifera aqueous crude extract (10, 50, and 100 mg/kg) and the reference drugs morphine (1 mg/kg) and acetylsalicylic acid (100 mg/kg) were evaluated in models of inflammation (formalin-induced licking and subcutaneous air pouch). The antioxidant activity was evaluated by 2,2-diphenyl-1-picryl-hydrazyl-hydrate (DPPH) photometric assay and compared with those of the standards (quercetin, rutin, and ascorbic acid). The extract was also screened against Candida albicans, Escherichia coli, Staphylococcus aureus, and methicillin-resistant Staphylococcus aureus (MRSA), in the agar diffusion method. The minimal inhibitory concentration (MIC) and minimal bactericidal concentration (MBC) were determined by the broth micro-dilution assay. Activities of combinations of the extract and antibiotics (methicillin or vancomycin) against MRSA were evaluated using checkerboard assays.
The extract significantly inhibited the time that the animals spent licking the formalin-injected paws (second phase). The extract also inhibited the inflammatory process induced by subcutaneous carrageenan injection by reducing cell migration, protein extravasation, and TNF-α production. Additionally, the extract showed an antioxidant potential in vitro as good as standards in their antioxidant activity. The extract was active only against S. aureus and MRSA. MIC and the bactericidal concentrations were identical (1,024 μg/ml). The extract and methicillin acted synergistically against the clinical MRSA isolate, whereas an indifferent effect was detected when the extract was combined with vancomycin.
The extract exhibits anti-inflammatory activity through the inhibition of the cell migration. The mixture of extract constituents and methicillin could lead to the development of a new combination antibiotic against MRSA infections.
- Cocos nucifera
- Anti-inflammatory activity
- Antioxidant activity
- Antimicrobial activity
The varieties of Cocos nucifera are found all over the tropical regions. In Brazil, there are different varieties like the “gigante” . The aqueous crude extract of husk fiber from C. nucifera is widely used in northeastern Brazilian traditional medicine to treat diarrhea and arthritis . During the past years, it has been shown that the “comum” C. nucifera has antibacterial, antiviral , antioxidant , anti-neoplastic [4, 5], and anti-inflammatory activities .
The variety “anão” is divided in “green”, “yellow” and “red”. The “mestiço” are known as segregated hybrids, resulting from aleatory cross between diverse plants, and thereby with unknown origin .
The inflammatory process is a complex phenomenon from vascular tissues to harmful stimuli, such as pathogens, damaged cells or irritants . In this paper, the anti-inflammatory action of an aqueous crude extract of husk fiber from C. nucifera was assessed in two animal models. Since, reactive oxygen species (ROS) have been implicated as novel second messengers that help regulate cellular events like inflammation , the free radical scavenging properties was either evaluated.
Besides the antioxidant and anti-inflammatory activities, the antimicrobial action was also evaluated by antibacterial and antifungal activities assays in this study, once the antimicrobial properties of the aqueous extracts of husk fiber from another Brazilian and Nigerian C. nucifera varieties were previously described [2, 9]. Since combination therapies may results in the administration of a lower dose of commercial antimicrobials, which might reduce drug toxicity and improve efficacy , combinations of the C. nucifera extract and commercial antimicrobials were also performed in this paper.
Considering that previous studies demonstrated the low toxicity of aqueous crude extract of husk fiber from other varieties of C. nucifera[3, 6], this is also expected for the “gigante” variety. In the popular use of this plant extract, the occurrence of adverse effects is not documented and aqueous crude extracts generally have low acute toxicities .
Furthermore, the use of the husk fiber might lead to the production of novel low-cost therapies and adjunct treatments because it is a by-product from the processing of C. nucifera. Therefore, the purpose of this study was to evaluate the anti-inflammatory, antioxidant and antibacterial activities of a variety of C. nucifera that has not been investigated yet, the “gigante”.
C. nucifera (Arecaceae) var. typica, commonly known as “gigante”, was collected in Sergipe, Brazil (Campo Experimental de Itaporanga, Embrapa Tabuleiros Costeiros) and authenticated by the forest engineer Humberto Rollemberg Fontes (Fitotecnia researcher). The characterization and identification of this variety was done following morphological, phenological, and production aspects of the plant, in addition to other criteria, such as age of the plant . A voucher specimen was deposited (number ASE- 27,441) at the Federal University of Sergipe.
Preparation of C. Nucifera crude extract
The water extract from husk fiber was prepared by infusion, as described previously . The use of aqueous extract was in accordance with the popular medicinal knowledge. The extract was filtered, lyophilized and stored at −20oC, yielding around 10% of the dry weight of starting material. For the experiments described below, the aqueous crude extract was re-suspended in distilled water. In the case of the antimicrobial assays, it was sterilized by filtration using a 0.22 μm membrane.
The lyophilized crude aqueous extract was submitted to HPLC/DAD analyses, according to a protocol devised by Peng et al.  to analyze procyanidins in grape seeds. Samples (20 μl) were loaded onto a 4.6 x 250 mm reverse phase RP-18 column (250 mm X 4,6 mm X 5 μm; XTerra®). Elution was achieved with solvents A (0.02% phosphoric acid in water) and B (82% acetonitrile, 0.04% phosphoric acid) as follows: 0 to 15% solvent B in the first 15 min, 15 to 16% from 15 to 40 min, 16 to 17% from 40 to 45 min, 17 to 43% from 45 to 48 min, 43 to 52% from 48 to 49 min, held isocratic at 52% from 49 to 56 min, reduced from 52 to 43% from 56 to 57 min, and from 17 to 0% from 58 to 60 min. Peaks were detected at 280 nm.
The concentration of procyanidins in the sample solution of C. nucifera lyophilized crude aqueous extract was determined by the vanillin-HCl assay . Briefly, 2.5 ml of methanol (control) or 1% vanillin solution in methanol (sample) and 2.5 ml of 9 M HCl in methanol was added to a test tube containing 1 ml of catechin solution (0 to 300 μg/ml in methanol) or test solution (150 to 250 μg/ml polyphenols in methanol). The reaction mixture was incubated for 20 min at 30°C, and the absorbance at 500 nm was measured. The absorbance was calculated as follows for each standard and sample solution: a calibration curve was prepared using the calculated absorbance for the catechin solution, and the total procyanidin in each test solution was calculated from the calibration curve.
All experiments were performed with male Swiss mice (20–25 g) obtained from our own animal facility. Animals were maintained in temperature-controlled room (22±2°C) with a 12 h light/dark cycles and free access to food and water. Twelve hours prior to each experiment, the animals received only water in order to avoid food interfering with the substance absorption. Animal care and research protocols (ICBDFBC-015) were in accordance with the principles and guidelines adopted by the Brazilian College of Animal Experimentation (COBEA), approved by the Ethical Committee for Animal Research (Biomedical Science Institute/UFRJ).
Drugs and extract administration
Acetylsalicylic acid (ASA) and morphine hydrochloride were purchased from Sigma (St. Louis, MO, USA) and Merck Inc. (Brazil), respectively. They were dissolved in sterile water just before use. The extract was dissolved in sterile water and administered by oral gavage at doses of 10, 50, and 100 mg/kg in a final volume of 0.1 ml. Morphine (1 mg/kg) and ASA (100 mg/kg) were used as reference drugs and were also administered by oral gavage. The negative control group received vehicle by oral gavage.
The formalin test was conducted in a manner similar to that described by Gomes et al. . Animals received an injection of 20 μl of formalin (2.5% v/v) into the dorsal surface of the left hind paw. The time that the animal spent licking the injected paw was recorded. The response consists of two phases. The first phase occurs 5 min immediately following the formalin injection (neurogenic pain response), and the second phase occurs 15–30 min after formalin injection (inflammatory pain response). The animals were pretreated with oral doses of extract, ASA, morphine or vehicle 60 min before the injection of formalin.
Subcutaneous air pouch (SAP) model
The method was similar to that described by Romano et al.  with several modifications described in Raymundo et al. . Briefly, air pouches were produced by subcutaneous injection of sterile air (10 ml) into the intrascapular region of the mice. After three days, another injection of air (10 ml) was performed in order to maintain the pouches. Three days after the last injection of air, animals received an injection of sterile carrageenan suspension (1%) into the SAP. Mice were pre-treated with oral doses of extract, ASA or vehicle 1 h before and 23 h after carrageenan injection in the SAP. Animals were sacrificed 24 h after carrageenan injection and the cavity was washed with 1 ml of sterile PBS. The total number of cells was determined with the aid of a haemocytometer. The exudates were centrifuged at 170 x g for 10 min at 4°C, and the supernatants were collected and stored at −20°C to further analysis. Supernatants from exudates collected in the SAP were used to measure tumor necrosis factor-α (TNF-α) and protein. TNF-α was quantified by enzyme-linked immunosorbent assay (ELISA), using the protocol supplied by the manufacturer (B&D, USA). The protein content of each supernatant was determined using the BCA method (BCATM Protein Assay Kit, Pierce).
Antioxidant activity determined by the 2,2-diphenyl-1-picryl-hydrazyl-hydrate (DPPH) photometric assay
The free radical scavenging activity of the C. nucifera extract was evaluated as described by Mensor et al. . Briefly, the plant extract was mixed with a 0.3 mM 2,2-Diphenyl-1-picryl-hydrazyl-hydrate (DPPH) ethanol solution, to give final concentrations of 0.78, 1.56, 3.13, 6.25, 12.5, 25, 50, and 100 μg of extract per ml of DPPH solution. After 30 min at room temperature, the absorbance values were measured at 518 nm and converted into the percentage of antioxidant activity. Free radical scavenging activity of the extract was compared with those of the quercetin, rutin, and ascorbic acid.
Microorganisms and antimicrobial standards
Methicillin and vancomicin were obtained from Sigma-Aldrich (Brazil) and stored according to the supplier’s instructions. The following reference strains were used: Staphylococcus aureus ATCC 6538 and the fungus Candida albicans ATCC 36802. The study also included a methicillin-resistant Staphylococcus aureus strain (BMB 9393) and a clinical isolate of Escherichia coli obtained from University Hospital of the Federal University of Rio de Janeiro.
The antimicrobial activity of the C. nucifera extract was evaluated by the agar diffusion method described by Hili et al. . Microorganisms (2 x 105 cells) were spread over appropriate plate (Brain Heart Infusion agar for bacteria and Sabouraud agar for the fungus). The extract was diluted in water (10 mg/ml), sterilized by filtration, and 10 μl aliquots of aqueous crude extract were applied to newly inoculated plates. Plates were incubated at 37°C for 24 h (bacteria) or for 48 h at room temperature (fungus).
Minimal inhibitory concentration (MIC) and minimal bactericidal concentration (MBC) assays
The MICs values of the extract against the test microorganisms were determined by broth microdilution method as recommended by CLSi . The microdilution method was also used to determine MBC values. The substances were transferred to a microplate in order to obtain two-fold serial dilutions of the original substance. Then, an inoculum (10 μl) containing 5×106 CFU/ml was added to each well and the microplates were aerobically incubated at 37°C for 24 h. Wells without inoculum added were used for sterility control, and the positive controls comprised of inoculated growth medium without the substances.
Bacterial growth was indicated by the presence of turbidity and a pellet on the well bottom, which was confirmed with 30 μl of resazurin (Sigma-Aldrich) added aseptically and incubated at 37°C for 1 h. The MIC was defined as the lowest extract concentration that was able to completely inhibit the bacterial growth. Methicillin and vancomicin were used as antimicrobial standards.
To evaluate whether the action of the extract was microbiostatic or microbicidal, 20 μl of the microbial culture were removed from wells with concentrations equal to, or higher than, the MIC, inoculated on BHI agar plates, and incubated at 37°C for 24 h. The MBC was defined as the lowest extract concentration at which all of the bacteria have been killed.
Synergistic activity of the extract and antimicrobial drugs against microorganisms
According to Mahboubi and Bidgoli , synergistic antimicrobial activity was evaluated by a checkerboard assay with the broth microdilution method. The extract and commercial antimicrobials were combined in concentrations lower than their individual MIC values by serial dilution in microplates. An inoculum (10 μl) containing 5×106 CFU/ml was added to each well and the microplates were incubated at 37°C for 24 h. The visual bacterial growth was confirmed with 30 μl of resazurin (Sigma-Aldrich) added aseptically and incubated at 37°C for 1 h.
Fractional inhibitory concentrations (FICs) were calculated as the MIC of the combination of the extract and a commercial antimicrobial divided by the MIC achieved when one of them was used individually. FIC index is widely accepted for use in evaluating in vitro synergistic actions. It is the sum of FICs values and indicates the nature of an interaction between two compounds. A FIC index between 0.5 and 4.0 indicates an insignificant interaction, whereas FIC index values <0.5 and >4.0 have synergistic and antagonistic interactions, respectively.
In vitro experiments (antimicrobial and antioxidant assays) were undertaken in triplicate sets. All animal groups were composed of 6–10 mice and the results are presented as the mean ± S.D. Statistical significance between groups was determined by analyses of variance (ANOVA) followed by Bonferroni’s test. p values less than 0.05 (*p< 0.05) were considered significant.
In order to corroborate the presence of these tannins, the vanillin-HCl assay was performed. This test is highly specific for procyanidins and involves acidic hydrolysis of the condensed tannins followed by coupling of the flavanol units to vanillin. Polymeric procyanidins were detected at a concentration of 103.80 ± 10.5 mg/g of aqueous extract.
Initially, the anti-inflammatory effect of the extract was evaluated by the formalin-induced licking model. The response consists of two phases and can evaluate both antinociceptive and anti-inflammatory activities. Centrally acting drugs, such as narcotics, are able to inhibit the two phases equally. The first phase involves direct chemical stimulation of nociceptive afferent fibers, leading to acute neurogenic pain. However, the second phase involves inflammation in the paw and central sensitization [22, 23].
One of the mediators that play an important role in the inflammatory process is TNF-α. It is released from activated monocytes and macrophages and increases vascular endothelial permeability . The production of this mediator was dramatically increased by the injection of carrageenan in the SAP. Nevertheless, the levels of this mediator in the exudates were significantly reduced in mice that received pre-treatment with the highest dose of extract (100 mg/kg) (Figure 4).
In vitro antioxidant activity
A good antioxidant effect of the aqueous crude extract of husk fiber from “olho de cravo” C. nucifera has already been determined by the same model (EC50= 10.0 ± 0.7 μg/ml). This activity could be attributed to the presence of condensed tannins in the husk fiber from C. nucifera.
Nevertheless, the extrapolation of an antioxidant effect in vitro to an in vivo action is not trivial. A direct antioxidant activity of flavonoids in vivo is likely to be limited to tissues in which relatively high concentrations of these compounds could be achieved, like in the digestive tract. In lower concentrations, they could support indirect antioxidant actions, like regulation of pro-oxidant enzymes and inhibition of protein–receptor coupling that initiates oxidant production .
However, the antioxidant activity can be related to an anti-inflammatory effect. Free radicals can attract inflammatory mediators contributing to a generalized inflammatory response . The reactive oxygen species are linked to increased endothelial permeability and leukocyte transendothelial migration . This can explain the inhibition of the carrageenan-induced protein leakage and the leukocyte migration by the extract of C. nucifera in the SAP.
Antimicrobial screening of C. nucifera extract by agar diffusion method
Esquenazi et al.  found that the “olho de cravo” C. nucifera has activity against one S. aureus ATCC strain and three clinical isolates of S. aureus. Further, Akinyele et al.  studied the aqueous extracts of the husk fiber from a C. nucifera variety from Nigeria. They demonstrated that it also has activity against S. aureus, in addition to inhibiting Gram-negative bacteria, such as Escherichia coli.
In accordance to the lack of reported activity of C. nucifera against Candida albicans in the literature, the “gigante” variety does not have effect against this fungus. Despite of being the same species of coconut, the different varieties have different types and quantities of substances in the fiber. The biological activity can be affected by structural variations, such as stereochemistry .
This may be the reason why the “gigante” variety does not have the same effects of the variety from Nigeria described by Akinyele et al. . In the present paper, the extract does not possess growth inhibitory activity against Escherichia coli. Nevertheless, it is important to note that the tested strain is different from that of the other study. Discrepancy in findings may be the result of the pathogen strains utilized or also be due to the variety of the plant and extraction process used.
Minimal inhibitory concentrations (MICs) of C. nucifera extract and antimicrobial drugs by the micro-dilution method
MIC was the same for the two bacteria strains tested (1024 μg/ml) and at this concentration, a microbicidal effect was observed. MIC values were also determined for methicillin. Methicillin-resistant staphylococcal is defined as MIC ≥ 4 μg/ml . To the methicillin-resistant strain, vancomicin was used as standard antimicrobial.
Despite having been able to killing the two strains of bacteria, the concentration of the extract was higher than those of the standards antimicrobial used. However, the MIC must be interpreted in the appropriate context. The raw extract is a mixture of active and non-active compounds and therefore higher MICs are expected .
Cos et al.  proposed an endpoint with concentration required to produce 50% growth inhibition below 100 μg/ml for extracts. Nevertheless, in the present study it was evaluated the extract’s concentration that was able to completely inhibit the bacterial growth and not only 50% growth inhibition. Thus, a higher MIC is acceptable. Webster et al.  interpreted a MIC value of crude plant extracts approximately to 1000 μg/ml as showing strong antifungal potential.
Effects of combinations of antimicrobial drugs and C. nucifera extract against MRSA
MIC of drug in combination
MIC of extract in combination
FIC of drug
FIC of extract
Nevertheless, the MIC value of methicillin against MRSA was lowered from 512 to 96 μg/ml when the extract was added at a concentration of 256 μg/ml (4-fold reduction in MIC). This combination had a FIC index calculated as 0.44, corresponding to a synergistic effect (Table 3). However, this synergistic effect was not able to reverse the methicillin resistance (MIC remained > 4 μg/ml).
The extract can be fractionated in order to check if the activity improved. In addition, the active substances in the extract and their modes of action should be further investigated. Moreover, the extract can lead to the development of novel inexpensive phytomedicines or models for synthetic substances.
The antistaphylococcal effect of the extract is important because MRSA and vancomycin-intermediate S. aureus are spreading worldwide and the pharmaceutical arsenal available to control antimicrobial-resistant bacteria is limited. Invasive infections by S. aureus are associated with significant morbidity and mortality, creating urgency in the development of new therapies and adjunct treatments that act against the resistant strains [33, 34].
Concerning the crude nature of the extract, the results allow concluding that it exhibited significant bioactivity and properties that support its uses in the folk medicine. The extract exhibits anti-inflammatory activity through the inhibition of the cell migration. In addition, the mixture of extract constituents and methicillin could lead to the development of a new combination antibiotic against MRSA infections.
Although the modes of action remain to be completely elucidated, the extract and its constituents might be promising candidates for the direct or adjunct treatment of inflammation and infection by MRSA, with low cost.
We would like to thank Renata S. Zardo (M.Sc.) for assistance in SAP model. Authors would like to thank Mr. Mark English for the English revision of the manuscript. The present work was supported by Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES), Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq), and Fundação de Amparo a Pesquisa do Estado do Rio de Janeiro (FAPERJ).
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