- 1Student Research Committee, School of Medicine, Bam University of Medical Sciences, Bam, Iran
- 2Department of Food Engineering, Faculty of Chemical and Metallurgical Engineering, Istanbul Technical University, Istanbul, Turkey
- 3Department of Gastronomy and Culinary Arts, School of Applied Sciences, Özyegin University, Istanbul, Turkey
- 4Bioactive Research & Innovation Food Manufac. Indust. Trade Ltd., Istanbul, Turkey
- 5Laboratory of Applied Mycology of Cariri, Department of Biological Sciences, Cariri Regional University, Crato, Brazil
- 6Laboratory of Planning and Synthesis of Drugs, Department of Antibiotics, Federal University of Pernambuco, Recife, Brazil
- 7Laboratory of Microbiology and Molecular Biology, Department of Biological Chemistry, Regional University of Cariri, Crato, Brazil
- 8Department of Agronomy, SAPVESA Laboratory, Nature and Life Sciences Faculty, University Chadli Bendjedid, El-Tarf, Algeria
- 9State University of Ponta Grossa, Department of Pharmaceutical Sciences, Ponta Grossa, Paraná, Brazil
- 10Department of Medical Biology, Faculty of Medicine, Nigde Ömer Halisdemir University, Campus, Nigde, Turkey
- 11Osmaniye Korkut Ata University, Bahçe Vocational School, Department of Food Processing, Osmaniye, Turkey
- 12Department of Botany, Lahore College for Women University, Lahore, Pakistan
- 13Phytochemistry Research Center, Shahid Beheshti University of Medical Sciences, Tehran, Iran
- 14Department of Horticulture, Faculty of Agriculture, University of Khartoum, Shambat, Sudan
- 15School of Pharmacy, Kumamoto University, Kumamoto, Japan
- 16Program for Leading Graduate Schools, Health Life Science: Interdisciplinary and Glocal Oriented (HIGO) Program, Kumamoto University, Kumamoto, Japan
- 17Department of Nutrition and Dietetics, Faculty of Pharmacy, Centre for Healthy Living, University of Concepción, Concepción, Chile
- 18Unidad de Desarrollo Tecnológico, Universidad de Concepción UDT, Concepción, Chile
- 19G. B. Pant National Institute of Himalayan Environment and Sustainable Development, Garhwal Regional Centre, Uttarakhand, India
- 20Department of Clinical Oncology, Queen Elizabeth Hospital, Hong Kong, China
- 21Faculty of Medicine, University of Porto, Alameda Prof. Hernâni Monteiro, Porto, Portugal
- 22Institute for Research and Innovation in Health (i3S), University of Porto, Porto, Portugal
Anacardium plants have received increasing recognition due to its nutritional and biological properties. A number of secondary metabolites are present in its leaves, fruits, and other parts of the plant. Among the diverse Anacardium plants' bioactive effects, their antioxidant, antimicrobial, and anticancer activities comprise those that have gained more attention. Thus, the present article aims to review the Anacardium plants' biological effects. A special emphasis is also given to their pharmacological and clinical efficacy, which may trigger further studies on their therapeutic properties with clinical trials.
Introduction
Anacardium plants have received an increasing attention in recent years. Among the Anacardium plants, Anacardium occidentale (cashew apple) leaf extract is traditionally used in treating various diseases in tropical America, especially in North-Eastern Brazil. Indeed, the popular drinks in Brazil include fresh and processed cashew apple juice. Cashew plants have been used for centuries as folk medicine in South America and West Africa. Quite a number of biological properties have been reported, among them antimicrobial, antioxidant, antiulcerogenic, and anti-inflammatory effects have drawn public attention. In Nigeria, these species have also been used to treat cardiovascular disorders. While in Brazil, these species are used as infusion for curing ailments (1).
Anacardium species contain various secondary metabolites in its leaf and shoot powder, fruits and other parts of the plant, which can be used regarding their nutraceutical, medicinal and biological aspects (Table 1).
Interestingly, cashew fruit is tasty and rich in minerals, vitamins, and some essential nutrients. It has high vitamin C, nearly to five times higher than oranges and also with high minerals content. The fruit comprises of some volatile compounds, e.g., esters, terpenes, and carboxylic acids (5). Cashew bark and leaves have a rich amount of tannins (6). Cashew nut kernel testa contains tannin as an interesting economical source of antioxidants that can be used for both food and nutraceutical purposes (7). The species also contain a rich amount of flavonoids with diverse physiological effects. Anacardic acids were detected in higher amount in nutshells. Cardanol (decarboxylated anacardic acid) and cardol are found as the main components of commercial cashew nut shell liquid. Cardanol is extensively used as a synthon for the synthesis of several polymers and agricultural products (8). Cashew nut shell liquid extracted by solvent is a mixture of alkenyl phenols, including anacardic acid. As defatted, cashew kernel flour is a good source of protein and minerals. Furthermore, it can serve as low-fat fabricated food and animal feed. Animal or poultry feeds are mostly formulated using a substantial amount of cashew fiber. Besides, cashew fiber along with cashew nut shell liquid, both possess high anacardic acids contents and therefore can be utilized in functional food formulations (9).
Anacardium Plants. Key Focus on Biological Effects
Herbal treatments are the most popular form of traditional medicine and commonly used as primary health care (10). All parts of cashew tree (mainly leaf and stem bark) have been extensively used as traditional herbal medicine, contributing health benefits all over the world (Table 2) (12, 37, 38). Thus, in the last decades, Anacardium plants folk medicinal properties, and multiple biological effects being studied extensively (Tables 3, 4).
Antioxidant Activity
Oxidation process produces free radicals which contain unpaired electron. They can cause DNA damages and attack lipids and proteins. Antioxidants can protect free radical-induced damages by transferring electrons or hydrogen. Thus, foods with antioxidants may provide defense against free radical damage in the body and may prolong the shelf life of food products.
Fermented fruit juice of A. occidentale was reported with high antioxidant activity (140). Tan and Chan (39) reported that fresh A. occidentale leaves exhibit high antioxidant and phenolic contents as assessed by 2,2-diphenyl-1-picrylhydrazyl (DPPH) radical scavenging, potassium ferricyanide, ferric reducing antioxidant power (FRAP), ferrous ion chelating ability, ferrozine, Folin–Ciocalteu, aluminiumchloride, and molybdate assays. Cashew apple juice and pulp have been reported to have considerable amount of vitamin C (141–144). High contents of polyphenols, tannins and dietary fiber were also reported (145). Furthermore, it was reported that copper, iron, zinc, and antioxidant compounds are also present in cashew apple juice, which were more abundant compared to cashew apple fiber (146).
In vitro Studies
A. occidentale revealed high antioxidant activity through DPPH radical scavenging, ferric thiocyanate, and thiobarbituric acid assays. However, it did not exhibit nitric oxide (NO) inhibitory activity (40, 147). Good antioxidant capacity of red and yellow cashew was also observed using 2,2'-azino-bis(3-ethylbenzothiazoline-6-sulfonic acid) (ABTS) and DPPH radical scavenging assays (148). Moreover, Kongkachuichai et al. (149) reported that young cashew leaves demonstrate high antioxidant capacity by oxygen radical absorbance capacity (ORAC) and FRAP assays.
Different parts of A. occidentale have strong antioxidant potency. For instance, ethanol extract of cashew nut skin demonstrated high total phenolic content and good antioxidant capacity as assessed by ABTS radical scavenging, superoxide scavenging, deoxyribose oxidation, and lipid peroxidation assays (150, 151). Andrade et al. (152) found that technical cashew nut shell liquid has high antioxidant capacity, perhaps due to its high content of cardanol and cardol, and thus it can be used as a natural antioxidant for nutraceutical and pharmaceutical purposes. The significant correlation between antioxidant capacity and the contents of anacardic acids, cardols, and cardanols was also reported, where anacardic acid content was found higher in cashew apple and fiber, whereas cardols and cardonols contents were higher in cashew nut shell liquid (9).
Antioxidant capacity of Semecarpus anacardium is also worth noting. Barman et al. (153) reported that S. anacardium nut ethanol extract had high antioxidant activity as assessed by DPPH and ABTS radical scavenging and metal chelating assays. It should be noted that antioxidant activities of plants can be affected by manufacturing process (154). Tan and Chan (39) reported that up to 30% decrease can be obtained in phenolic content and antioxidant activity of A. occidentale after blanching. However, no changes due to microwave treatment was observed. Interestingly, Trox et al. (155) reported that bioactive content of cashew nut kernels decreased after conventional shelling techniques, such as oil-bath roasting, steam roasting, drying, and open pan roasting; and they recommended flores hand-cracking method to minimize losses. Moreover, the contents of vitamin C, flavonoids, and polyphenols in cashew apple juice were increased after cold plasma treatment. Yet decreases in bioactive contents were observed at excessive exposure (156). Liao et al. (157) reported that antioxidant activity of cashew nut kernels were not affected by hot air-assisted radio frequency roasting. Moreover, sonication treatment improved the bioactive compound extraction yield from cashew apple bagasse compared to conventional heat treatment, and the optimum conditions were recommended as treatment for 6 min at an intensity of 226 W/cm2 and 1:4 bagasse-to-water ratio resulting the highest vitamin C and total phenolic contents (158). In addition, total phenolic and tannin contents of A. occidentale were increased by gamma-irradiation (159).
There are changes in the antioxidant and phenolic contents of cashew during ripening. Gordon et al. (41) observed a decrease in phenolic content of cashew apple during ripening compared unripe apple, but ascorbic acid concentration and antioxidant activity was increased during ripening. Thus, it is plausible that the antioxidant activity of cashew apple may depend on ascorbic acid rather than phenolic content (41).
The antioxidant capacity of anacardium also depends on the extraction method. Razali et al. (42) reported that A. occidentale shoots methanol extract exhibited higher antioxidant activity compared to ethyl acetate and hexane extracts as assessed by ABTS, DPPH, superoxide anion, and NO radical scavenging assays; moreover, total phenolic content of methanol extract was found to be higher. De Abreu et al. (160) reported that carotenoids content of cashew apple was higher compared to aqueous extracts. In another study, it was observed that ethyl acetate extract of S. anacardium stem bark exhibited higher phenolic content compared to that of hexane and chloroform extracts (161). Chotphruethipong et al. (162) recommended extraction at 34.7°C for 64 min with ethanol-to-solid ratio of 18:1 (v/w) as optimum conditions for cashew leaves extraction. Aqueous, ethanol and petroleum ether (60–80°C) extract from A. occidentale leaves were studied for antioxidant activities through NO production and DPPH radical assays. Ethanol extract revealed the higher potential, followed by aqueous and petroleum ether extracts (43).
The antioxidant effect of A. occidentale leaf extract was measured and exerted noticeable activity in treating RAW 264.7 macrophage cells. Leaf extract administration (0.5 and 5 μg/mL doses) reduced oxidative damage in macrophage cells. Moreover, oxidative damage attributes induced in lipopolysaccharide (LPS)-stimulated RAW 264.7 macrophage cells was inverted by leaf extract (44). Antioxidant activity of whole cashew nuts products, treated with low- and high-temperature was also determined. Results indicated that antioxidant activities of cashew nut, kernel, and testa phenolics extracted increased with the increasing roasting temperature. The highest activity was observed in nuts roasted at 130°C for 33 min, as revealed by DPPH, ORAC, Trolox equivalent antioxidant capacity (TEAC), FRAP, and hydroxyl radical scavenging assays (163). Frozen cashew pulps from A. occidentale were investigated for antioxidant activity using FRAP and DPPH assays (164).
Methanol, hexane and ethyl acetate extracts of A. occidentale shoots were investigated through using ABTS and DPPH radicals, superoxide anion radicals, NO radicals, and ferric ions reducing assays. A. occidentale methanol extract was the most potent reducing agent and radical-scavengers. In case of ethyl acetate extract, some antioxidant effects were detected, and hexane extract was the least reactive. Methanol extract revealed 7-fold higher total phenolic content than the hexane and ethyl acetate extracts, suggesting the possible contribution of phenolics in the observed effects (42). Anacardium microcarpum antioxidant effects were also investigated on human leukocytes and erythrocytes using in vitro methods. The half maximal inhibitory concentration (IC50), for DPPH, varied from 27.9 (ethyl acetate fraction) to 32.9 μg/mL (ethanol fraction), and Fe2+ (10 μM)-induced lipid peroxidation was strongly inhibited by all fractions in rat brain and liver homogenates. Interesting, all the studied fractions were not cytotoxic to leukocytes and were able to inhibit against H2O2-induced cytotoxicity. No effects was found on human erythrocytes osmotic fragility, thus suggesting that A. microcarpum infusion can be safely consumed (1).
In vivo Studies
Technical cashew nut shell liquid decreased oxidative stress induced by paraquat or H2O2 exposure in Saccharomyces cerevisiae, demonstrating the antioxidant activity in the in vivo model assessed by DPPH scavenging and xanthine oxidase assays (152). Moreover, Encarnação et al. (15) observed antioxidant activity of A. occidentale stem bark by total phenolic content and DPPH scavenging assays, and they also reported that an oral dose of 2,000 mg/kg does not possess genotoxicity as assessed by in vivo tests on mice. Pereira et al. (165) observed antioxidant activity in rats fed with mixed tropical fruit juices containing 5% cashew apple.
The antioxidant capacity of Anacardium plants can also be related to the antimicrobial and anticancer properties. For instance, Premalatha and Sachdanandam (166) reported that S. anacardium nut extract has anticancer properties, and it was related to the high antioxidant capacity of the product, as it triggered antioxidant defense system in an in vivo study performed on male Wistar rats. The antioxidant effects of S. anacardium were also investigated by Ramprasath et al. (167) on arthritic rats. The results of this study shows that S. anacardium extract restored the increment in C-reactive protein and erythrocyte sedimentation rate observed in arthritic animals.
Antimicrobial Activity
The ethnomedicinal use of Anacardium plants for the treatment of bacterial and fungal infections is practically limited to A. occidentale (Table 5). The applicability of this plant for these therapeutic purposes has been reported in South America, Central America, Africa, and Asia. The bark is commonly used, although the leaves, roots, seeds, and fruits also can be utilized. Despite many ethnobiological studies omitting information regarding preparation, decoction is more incidental and oral administration predominates. The species is mainly used for gastrointestinal and skin disorders, where these can be caused by action of various bacterial and fungal species. On the other side, the adaptive capacity of microorganisms has contributed to their resistance to current drugs available, with this encouraging the search for new antimicrobial substances (179).
In vitro Studies
Antibacterial properties
In antibacterial property of medicinal plants from Nigeria, A. occidentale hydroethanolic extracts (leaf/bark) showed positive effects against Escherichia coli, Staphylococcus aureus, Enterobacter species, Streptococcus pneumoniae, Corynebacterium pyogenes, Enterococcus faecalis, multiresistant S. aureus, Acinetobacter species, Pseudomonas aeruginosa, and multiresistant P. aeruginosa during cavity diffusion tests with inhibition halos varying from 6 to 14 mm (18).
In the study by Akinpelu (29), A. occidentale bark methanol extract (60%) exhibited antimicrobial activity against 13 out of 15 bacterial isolates, obtaining the activity against Shigella dysenteriae and Klebsiella pneumoniae, using the agar and broth microdilution methods (20 mg/mL). In the study by Melo-Cavalcante et al. (45), the antibacterial effect of fresh (25, 50, and 100 μL/plate) and processed (100, 500, and 2,000 μL/plate) cashew juices (A. occidentale) were assessed against Salmonella typhimurium, and all tested doses revealed to be effective. Melo et al. (180) demonstrated the action of the A. occidentale stem bark hydroalcoholic extract against Streptococcus mitis, Streptococcus mutans, and Streptococcus sanguis using diffusion and microdilution techniques. The extract concentrations (50 to 0.04 mg/mL) presented halos varying from 19 to 0 mm for S. mitis, 16 to 20 mm for S. mutans and 18 to 20 mm for S. sanguis. Chlorhexidine (0.12 to 0.001875%) obtained inhibition halos of 14 to 12 mm. The bacterial surface adherence analysis revealed the extract interferes with adhesion at 0.31 and 0.15 mg/mL.
Silva et al. (181) demonstrated that methicillin resistant and sensitive S. aureus samples were sensitive to pure (100 mg/mL) and diluted (1:2-1:64) A. occidentale stem bark extract, presenting inhibition halos ranging from 10 to 20 mm. The norfloxacin control inhibition halos ranged from 11 to 36 mm.
The liquid from A. occidentale cashew bark was evaluated as a food additive for ruminants, where prior to its addition to feed, cashew nut shell liquid was tested by microdilution (0 to 50 μg/mL). The lower MIC values were obtained (1.56–6.25 μg/mL) against Ruminococcus flavefaciens, Ruminococcus albus, Ehrlichia ruminantium, and Butyrivibrio fibrisolvens and moderate values (25 to 50 μg/mL) against Streptococcus bovis and Lactobacillus ruminis. Four of the tested bacteria (Succinivibrio dextrinosolvens, Ruminobacter amylophilus, Elenomonas ruminantium, and Megasphaera elsdenii) were insensitive to cashew nut shell liquid (MIC ≥ 50 μg/mL). The bacteria Fibrobacter succinogenes, Prevotella ruminicola, and Succinimonas amylolytica were sensitive to the cashew nut shell liquid (MIC: 3.13 to 12.5 μg/mL). Thus, cashew nut shell liquid inhibits rumen-specific bacteria and its activity is promising (182).
The dried extract obtained from A. occidentale leaf powder dye (20%; 200 mg/mL) showed an effect against S. aureus which produced the largest inhibition halo (12 mm). In comparison, gentamicin and chloramphenicol produced halos of 20 and 21 mm, respectively (98).
Campos et al. (183) evaluated two A. occidentale starch (10 to 60 mg/mL) samples (crude and purified) against E. coli, S. aureus, Listeria innocua, P. aeruginosa, Enterococcus faecium, and Lactobacillus acidophilus strains. Both samples were able to inhibit growth, with MICs ranging from 20 to 30 mg/mL for the crude starch, and 40 to 60 mg/mL for the purified starch. The result was obtained for P. aeruginosa (20 mg/mL). In the subculture assay (Minimum bactericidal concentration, MBC), only the purified starch sample displayed action at 50 mg/mL. In the cell's structural analysis, changes such as pili loss and cell lysis (10 mg/mL) were observed.
Kaewpiboon et al. (184) confirmed the action of A. occidentale dry leaf ethanolic extract (5%) by disc-diffusion and microdilution, obtaining 15- and 13-mm inhibition halos and MICs of 250 and 500 μg/mL against E. coli and P. aeruginosa, respectively. Chloramphenicol (20 μg/disc) obtained a diameter varying from 15 to 30 mm and a MIC ranging from 7.1 to 125 μg/mL.
The methanolic and n-hexane extracts from A. occidentale aerial parts showed inhibitory effects against bacteria (S. aureus, E. faecalis, E. coli, P. aeruginosa, K. pneumoniae, and Mycobacterium smegmatis) with MICs ranging from 62.5 to 250 μg/mL (n-hexane) and 7.5 to >250 μg/mL (MeOH), with the effect for both extracts being obtained against S. aureus (185). A. occidentale bark ethanolic extract (3.125, 6.25, 9.375, and 12.5 mg/mL) was investigated against Streptococcus sanguinis biofilm formation. The extract inhibited biofilm formation as the concentration increased, ranging from 67.22 to 94.20%. The chlorhexidine control (0.12%) presented 89.55% inhibition (186).
An A. occidentale tincture (20%) obtained from a homeopathic Pharmacy was tested for oral bacteria biofilm-forming inhibition, and MICs of 3.12 and 0.78 mg/mL were obtained against S. mutans and Streptococcus oralis by microdilution (187). As for the diffusion, the tincture (pure 1:1) from the same Anacardium species obtained from a Manipulation Pharmacy (diluted in 20% in 70% alcohol) showed inhibition halos of 12, 13, 11, and 15 mm against S. mutans, S. salivary, E. faecalis, and Eikenella corrodens, respectively. For Chlorhexidine, the values obtained were 17, 15, 17, and 19 mm respectively (188).
Menezes et al. (78) extracted tannins from A. occidentale stem bark and evaluated by cavity diffusion its antibacterial effect against S. mutans, S. mitis, S. sanguis, Streptococcus salivarius, and Lactobacillus casei at 1:1, 1:2, to 1:16 μg/mL, with inhibition halos ranging from 11 to 17 mm. In the presence of 5% sucrose, the bacterial anti-adherence effect was observed using concentrations from 1:8 to 1:512 μg/mL, obtaining in some cases, a better effect than 0.12% chlorhexidine gluconate (1:16–1:32 μg/mL).
Fresh and processed (bleached and irradiated) leaves extracts of A. occidentale showed antibacterial effect. The minimum inhibitory doses capable of forming inhibition halos were 0.06 to 0.50 mg/disk, having an effect against Brevibacillus brevis, Micrococcus luteus, Staphylococcus cohnii, E. coli, and P. aeruginosa with the best performance being obtained for the irradiated extract (39). The A. occidentale leaf extract was investigated by Ayu et al. (189) against Aggregatibacter actinomycetemcomitans, a bacterium responsible for gingivitis. Inhibition zones ranging from 4.47 to 8.05 mm were observed for the tested concentrations (8, 41, 145, 164, 189, 190), and 96%) using agar diffusion method. The metronidazole control displayed a halo of 13.91 mm.
The cashew pulp juice extract (1 at 7.8 mg/mL) was tested against S. aureus planktonic cells and for the first time, against S. aureus biofilms where the cashew pulp juice extract was also tested in association with antimicrobials using the broth microdilution method and MBC. A MIC of 15.6 μg/mL, a MBC of 125 μg/mL and a biofilm Eradication Concentration of 500 μg/mL were obtained, demonstrating its antimicrobial and antibiofilm activity (79). The crude A. occidentale hydroalcoholic extract bark also showed good effects against S. aureus through disk diffusion (20 μL), presenting an inhibition halo of 11 mm (191).
In the study by Muraina et al. (192), A. occidentale leaf extract (10,000 μg/mL) was used against Mycoplasma spp., using the broth microdilution method. The antibiotic tylosin (1,280 μg/mL) was used as a positive control and acetone as a negative control. The authors obtained a significant result for the extract as an anti-mycoplasm product (MIC = 310 μg/mL).
Cajado et al. (193) investigated the aqueous and hydroalcoholic A. occidentale dry leaf limb extract against E. coli, S. aureus, and K. pneumoniae strains. The agar diffusion technique demonstrated S. aureus inhibition at 75 and 150 mg/mL (aqueous: 9.5 mm and hydroalcoholic: 8 and 10 mm). Moreover, amoxicillin in association with clavulanic acid (30 μg/mL) presented an action ranging from 12 to 38 mm.
Harsini (194) investigated the action of A. occidentale stem bark ethanolic extract against S. aureus by analyzing Ca2+ and K+ ion leakage inside the bacterial cell. Ca2+ leakage at 0% (control), 3, 5 and 7% concentrations varied from 2.42 to 66.73 mM, and for K+ this ranged from 15.28 to 1,251 mM, destabilizing the cell.
Quelemes et al. (195) evaluated the A. occidentale cashew starch (CG) antibacterial effect by microdilution, as well as that of its quaternized derivatives (QCG-1, QCG-2, and QCG-3) against a series of bacteria. QCG-2 and QCG-3 presented antimicrobial activity against S. aureus and Staphylococcus epidermidis (standard and resistant) where a MIC of 31.5 to 250 μg/mL and a MBC of 62.5 to 500 μg/mL were obtained. These results show the quaternized derivatives may be a promising tool in the development of biomaterials with antiseptic action.
The purified A. occidentale bark liquid was able to inhibit Bacillus subtilis growth (0.6%) and alter its morphology (0.4%). The activity of the purified cashew nut shell liquid was tested using the colony counting method, where an IC50 of 0.35% (v/v) was observed, presenting a bactericidal effect as well as cellular elongation suggesting bacterial cell division proteins may be a cashew nut shell liquid target (196).
Dos Santos et al. (197) obtained crude and fractionated extracts [hexane, dichloromethane, ethyl acetate, and methanol: ethyl acetate (9:1)] from A. occidentale leaves and evaluated these before and after being irradiated with gamma radiation, showing its effect over several S. aureus species was intensified after gamma radiation exposure (non-irradiated: MIC of 500 to >2,000 μg/mL, irradiated: MIC of 250 to >2,000 μg/mL).
De Araujo et al. (198) tested by microdilution, extracts rich in tannins obtained from A. occidentale stem bark which inhibited cariogenic bacteria growth from the Streptococcus genus, obtaining a MIC of 3,125 μg/mL (S. mitis, S. mutans) and of 6.25 μg/mL (S. oralis, S. salivarius, S. sanguinis, and Streptococcus sobrinus). The 0.12% chlorhexidine control presented MICs ranging from 0.390 to 3,125 μg/mL.
A. occidentale cashew bark oil (heated and raw-−1,600 to 0.7812 μg/mL) as well as 16 isolated compounds (anacardic acids, cardols and cardanols) were investigated by Himejima and Kubo (99). Using microdilution method, the following strains were tested: B. subtilis, Brevibacterium ammoniagenes, S. aureus, S. mutans, E. aerogenes, E. coli, P. aeruginosa, and Propionibacterium acnes. The oil's best result was obtained against B. subtilis (heated: 6.25 μg/mL and crude: 12.5 μg/mL) and S. mutans (heated: 3.13 μg/mL and crude: 3.13 μg/mL). The isolates obtained MIC values ranging from 0.39 to 100 μg/mL, with P. acnes being the most susceptible strain. Kubo et al. (199) isolated from A. occidentalis cashew, and tested through microdilution, a series of anacardic acids and (Z)-2-alkenyls against H. pylori, obtaining MIC values ranging from 200 to 800 μg/mL.
In the study by Green et al. (200), a series of anacardic acid analogs (200 μg/mL) extracted from A. occidentale with different side chains were evaluated, where phenolic, branched and alicyclic analogs were synthesized and their antibacterial activity was tested against methicillin-resistant S. aureus (MRSA) using microdilution method. The result was obtained for the side chain branched analog, 6-(40,80-dimethylnonyl) salicylic acid, and the side chain alicyclic analog, 6-cyclododecylmethyl salicylic acid (MIC = 0.39 μg/mL), respectively. This activity was greater than that of the most potent isolated antibacterial anacardic acid.
Based on the previous antibacterial anacardic acid study, 6-pentadecenyl salicylic acids isolated from A. occidentale cashew tree, a series of 6-alk(en)yl salicylic acids (200 μg/mL) were synthesized and tested for their antibacterial activity against S. mutans using broth microdilution. Among these, 6-(40,80-dimethylnonyl) salicylic acid was found to exhibit the most potent antibacterial activity against this cariogenic bacterium with a MIC of 0.78 μg/mL (201).
S. aureus and Streptococcus pyogenes were sensitive to A. occidentale cashew hexane and anacardic acid (both 20 mg/mL) extracts. When using agar diffusion, 18- and 16-mm halos were obtained for the extract and 16 mm for the acid, while microdilution analysis revealed MIC values ranged from 20 to 1:256 mg/mL. The amoxicillin control (20 mg/mL) inhibited total growth in the strains (179).
Anacardic acid (2, 10, 50, and 250 μg/mL) extracted from the cashew bark oil (A. occidentale) inhibited S. aureus biofilm formation at 40, 76, 80, and 99.96% as the concentration increased. The acid also reduced S. aureus adherence to catheters by 20% at the lowest tested dose (202). A. occidentale stem bark methanolic extract and isolated compounds (Pinostrobin, Pinocembrin, and 4-hydroxybenzaldehyde) presented inhibition zones, through disc diffusion, varying from 6.43 to 12.56 mm against Salmonella dysenteriae, Salmonella typhi, S. aureus, and E. coli, with the best results being obtained using Pinocembrin. Chloramphenicol exhibited inhibition zones of 18.71 to 21.50 mm. The IC50 varied from 62.5 to 500 (4,098 μM), with the best effect being obtained using the extract against all strains (46).
These studies using the A. occidentalis species prioritized the evaluation of hydroethanolic and methanolic extracts, using mainly the stem bark from the species. The method chosen for most of the tests was microdilution, followed by disk diffusion. Moreover, isolated compounds have already been evaluated, mostly anacardic acids. In addition to A. occidentale, two other species, A. microcarpum and Anacardium humile were tested against bacteria.
The crude ethanolic extract, ethyl acetate fraction and methanolic fraction from fresh A. microcarpum bark had their intrinsic antibacterial activity evaluated displaying antibacterial activity at 512 μg/mL (E. coli, P. aeruginosa, and S. aureus), which when combined with antibiotics, potentiated the effect of amikacin and gentamicin against the strains (134).
In another study by Barbosa-Filho et al. (1), A. microcarpum ethyl acetate fraction and methanolic fraction were tested in isolation or in combination with antibiotics (amikacin, gentamicin, ciprofloxacin, and imipenem) against E. coli, P. aeruginosa, and S. aureus. All extracts revealed low antibacterial activity against multiresistant strains (MIC = 512 μg/mL). However, the association of natural products with antibiotics presented a synergistic effect against the multiresistant E. coli strain. Moreover, the extract and ethyl acetate fraction, in conjunction with amikacin and gentamicin, also demonstrated synergism with imipenem against S. aureus.
Pereira et al. (203) evaluated three extracts (20 mg/mL) from A. humile leaves (ethanol, butanol, and hexane fractions) against S. mutans, S. aureus, and A. actinomycetemcomitans by agar diffusion and broth microdilution. Inhibition halos ranged from 9 to 19 mm, with the best result being obtained for ethanolic extract against S. aureus. MIC evaluation revealed a 0.50 mg/mL value for S. mutans, 1 mg/mL for S. aureus, and 3.50 mg/mL for A. actinomycetemcomitans. Chloramphenicol (10 μg/mL) presented halos ranging from 19 to 36 mm.
Antifungal Properties
The increase in fungal resistance and the incidence of infections has led to the realization of tests aiming to evaluate the antifungal potential of species from the Anacardium genus against primary and opportunistic pathogenic fungi.
A. occidentale stem bark extract (1:1 to 1:512 mg/mL) presented action against Candida tropicalis and Candida stellatoidea strains with inhibition halos ranging from 17 to 12 and 18 to 12 mm, respectively, where the chlorhexidine gluconate control obtained halos ranging from 12 to 22 mm (204). Bahadur et al. (205) found that A. occidentale cashew bark methanol extract (150, 200, and 300 ppm) reduced conidia germination (11% at 300 ppm) of Erysiphe pisi in humid chambers for analysis under the microscope. Kolaczkowski et al. (190) assessed the A. occidentale methanol extract (aerial parts) effect against Candida glabrata, by broth microdilution, obtaining a MIC of 0.08 mg/mL, while that of the control drug fluconazole was 0.008 mg/mL.
A. occidentale burnt cashew pulp extract was evaluated against fungi from the Fusarium genus. Disc diffusion assay revealed the action of burnt cashew pulp extract (5 mg/mL) on Fusarium oxysporum (±30%), Fusarium moniliforme, and Fusarium lateritium (±60%) growth decrease. KHCO3 (20 mg/mL) control had a zone ranging from ±15% to ±28%, and the Cercobin fungicide (10 ppm) had a zone ranging from ±25 to ±30% (206).
Harsini (207) observed through colony counting that rinse solutions made from the A. occidentale bark ethanol extract (1, 2, 3, 4, and 5%) influenced C. albicans adherence to acrylic resin. The number of colonies ranged from 1757.50 to 670.00 CFU/mL, showing better results than the control (1912.50 CFU/mL).
Santos et al. (159) observed that A. occidentale leaf and bark hydroalcoholic extracts (70%) had their action improved when exposed to gamma irradiation (0, 5.0, 7.5, and 10 kGy). Disc diffusion assays showed that, against C. albicans, the extracts (2,000 μg/disc) presented halos ranging from 14 to 0 mm and from 58 to 0 mm for bark and leaves, respectively. A. occidentale tincture (200 mg/mL) obtained from a Homeopathic Pharmacy was tested by microdilution and presented action against C. albicans and Candida krusei with a MIC value of 100 mg/mL. No growth was observed with the control nystatin (100,000 IU/mL) (187). A. occidentale dried leaf ethanolic extract (20 mg/mL) was tested by Anand et al. (80) against C. albicans presenting 15.67 mm inhibition halos, with gluconate (CHX) and povidine iodine (PI) presenting 14.67 and 19.67 mm, respectively. In the microdilution assay (10,000 μg/mL), the MIC and Minimum Fungicide Concentration (MFC) of the extract obtained a value of 1,250 μg/mL (CHX-−5 μg/mL and PI-−40 and 80 μg/mL, respectively). In the biofilm assay, the density for the extract obtained was of 0.107 nm, with a potent action compared to the controls (CHX: 0.102 nm and PI: 0.186 nm).
Muzaffar et al. (139) tested anacardic acid (0 to 100 μM) against Magnaporthe oryzae. A strong conidial germination inhibition was observed by counting colony forming units in samples treated with anacardic acid (75 μM-−70%), while no inhibition was observed in the control containing dimethyl sulfoxide (DMSO-−0.1%).
Mahata et al. (208) evaluated the cardanol activity extracted from A. occidentale cashew, and its derivatives against C. albicans. The best MIC values were obtained for 4-[(4-cardanyl)azo] benzoic acid (CABA) hydrogel derivatives (8 μg/mL), followed by Self-assembled CABA (16 ug/mL) and cardanol (64 μg/mL). Drastic damages (lysis) caused by products in the fungus's membrane and cell wall were observed using scanning electron microscopy, especially by the CABA compound.
A. humile dried leaf (50 and 400 μg/mL) hydroalcoholic extract and its fractions (hexane, dichloromethane, ethyl acetate, and isobutanol) presented activity against C. albicans. Microdilution test revealed strong inhibition at 400 μg/mL for both extracts and fractions (133).
Investigations reporting the antifungal activity of Anacardium species mostly highlighted the A. occidentale species, in a similar manner to the antibacterial activity. The hydroethanolic extract was the most commonly tested extract type with the bark being the most commonly investigated plant part through microdilution and against opportunistic Candida spp. pathogens. No in vivo studies have been reported and no reports have been found against dermatophyte fungi. As observed in ethnobiological research, the medical use of this genus is the treatment of gastrointestinal symptoms and skin disorders and, therefore, studies carried out involving fungi which act with this pathogenesis profile are of extreme relevance.
Anticancer Activity
Cancer is the major cause of death worldwide, researchers are working to develop more therapeutic components for cancer treatment with less side effects. Plants are the main sources of pharmacologically active molecules, used for therapeutic purposes (209–211).
Taiwo et al. (26) conducted a study with Nigerian A. occidentale leaves in cultured HeLa cells. Four isolated compounds, zoapatanolide A, agathisflavone, anacardicin, and methyl gallate, were identified, and authors found that these components exhibited HeLa cell viability reduction in dose-dependent manner, although with distinct efficiencies: zoapatanolide A > anacardicin > agathisflavone > methyl gallate. The cytotoxic potential of zoapatanolide A is well-documented in literature (212). This class of compounds act as Michael acceptor for the cysteines thiol groups, covalently modifying proteins (213, 214). Kubo et al. (215) found that the biflavonoid, agathisflavone, has antiproliferative activity against Jurkat cells (IC50 = 4.45 μM), although other compounds isolated from A. occidentale juice have also revealed cytotoxic abilities, such as anacardicin, gallic acid, and other salicylic acid derivatives. The agathisflavone effect in several cancer cell lines (colon, lung, renal, breast, and ovarian cancer) was assessed, but only a marginal activity was stated, while to the methylated derivatives promissory effects were listed against these cancer cells (216) and even against chronic myeloid leukemia cell line K562 (217). Later, the agathisflavone effect on leukemia cells growth was further studied by Konan et al. (218); this compound induced lymphopenia in vivo and selectively triggered apoptosis. In addition, it was also stated that in Jurkat cells the antiproliferative ability of agathisflavone is more effective than on acute promyeloid leukemia (APL) cell line HL60, with IC50 of 2.4 and 11.03 μg/mL, respectively. On the other hand, the identification by liquid chromatography–mass spectrometry (LC-MS) of the cashew nut shell liquid purified from Indian A. occidentale, revealed a chemical composition of cardanol, anacardic acid, and methyl cardol. It inhibited HeLa cells proliferation, triggered moderate mitotic block and HeLa cells apoptosis, besides to accelerate wound closure in L929 cells, without causing toxic effects on normal cells (196).
Kishore et al. (219) reported that anacardic acid enhance aurora kinase A activity through induction of structural changes. This compound exerted cytotoxic effects on several human cancer cell lines in vitro. In view of histone acetyltransferase (HAT) inhibition, cashew nut shell liquid, anacardic acid, and their derivatives were assessed for tumor suppressing effects. There were no-mutagenic effects up to 0.003% with and without S. typhimurium strains metabolic activation (220). Anacardic acid also inhibited cardiomyocytes hypertrophy in isolated neonatal rat in response to phenylephrine or urocortin. Anacardic acid was also as effective as Spiruchostatin A (221).
Anacardic acid-induced Aurora kinase A autophosphorylation was shown in an in silico approach, and this effects was attributed to its ability to bind and induce structural changes on the enzyme (219). Furthermore, Schultz et al. (222) stated that anacardic acid displayed effective inhibition toward estrogen receptor alpha (ERα)-expressing breast cancer cells proliferation, regardless of endocrine/tamoxifen sensitivity, while no effect was observed in ERα-negative cells. In addition, cell cycle progression inhibition and apoptosis induction in ERα -expressing cells was stated ERα-dependently. In short, as anacardic acid inhibited ERα-expressing breast cancer cells proliferation, but not the primary HuMECs, this finding reveals of utmost interest for further delineation of medical actions in cancer therapy.
Besides, marked effects were also reported by Sukumari-Ramesh et al. (223) on pituitary adenoma cells. Anacardic acid triggered polymerase cleavage induction, sub-G1 arrest, and annexin-V expression, reduced survivin and X-linked inhibitor of apoptosis protein and anti-apoptotic proteins expression, all associated with cell survival. However, carbobenzoxy-valyl-alanyl-aspartyl-(O-methyl)-fluoromethylketone failed to revert anacardic acid-induced cell death. Moreover, Chandregowda et al. (224), tested diverse benzamide derivatives synthesized for cytotoxic capacity on HeLa cells, being these compounds classified as potent as garcinol, with interesting IC50 values.
Conclusions and Future Perspectives
Anacardium plants have extensively been largely reported for its antioxidant, anti-inflammatory, anticancer, and antimicrobial effects. A number of in vitro studies have been reported with promising results. On the other hand, the anticancer potential of Anacardium secondary metabolites is also quite prominent. Thus, Anacardium plants should be further studied to better elucidate their therapeutic potential not only in the in vitro and in vivo studies, but also the clinical application.
Author Contributions
JS-R: conceptualization. JS-R, MM, AJ, WC, and NM: reviewed and editing. All authors: validation investigation, resources, data curation, writing, read and approved the final manuscript, and contributed equally to the manuscript.
Conflict of Interest
BÖ was employed by the company Bioactive Research and Innovation Food Manufac. Indust. Trade Ltd.
The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Acknowledgments
AJ acknowledged the funding from Uttarakhand council for Biotechnology, Pantnagar, Uttarakhand, India (File No. UCB/R&D Project/2018-311) for this work. MM would like to thank the support offered by CONICYT PIA/APOYO CCTE AFB170007.
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Keywords: Anacardium, cashew nut, phytotherapy, antioxidant, antimicrobial, anticancer
Citation: Salehi B, Gültekin-Özgüven M, Kirkin C, Özçelik B, Morais-Braga MFB, Carneiro JNP, Bezerra CF, Silva TG, Coutinho HDM, Amina B, Armstrong L, Selamoglu Z, Sevindik M, Yousaf Z, Sharifi-Rad J, Muddathir AM, Devkota HP, Martorell M, Jugran AK, Cho WC and Martins N (2020) Antioxidant, Antimicrobial, and Anticancer Effects of Anacardium Plants: An Ethnopharmacological Perspective. Front. Endocrinol. 11:295. doi: 10.3389/fendo.2020.00295
Received: 24 February 2020; Accepted: 20 April 2020;
Published: 12 June 2020.
Edited by:
Wen Zhou, Case Western Reserve University, United StatesReviewed by:
Domenico Iacopetta, University of Calabria, ItalyGiovanni Luca, University of Perugia, Italy
Copyright © 2020 Salehi, Gültekin-Özgüven, Kirkin, Özçelik, Morais-Braga, Carneiro, Bezerra, Silva, Coutinho, Amina, Armstrong, Selamoglu, Sevindik, Yousaf, Sharifi-Rad, Muddathir, Devkota, Martorell, Jugran, Cho and Martins. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Javad Sharifi-Rad, javad.sharifirad@gmail.com; Miquel Martorell, martorellpons@gmail.com; Arun Kumar Jugran, arunjugran@gmail.com; William C. Cho, chocs@ha.org.hk; Natália Martins, ncmartins@med.up.pt