Phytochemical profile, evaluation of antimicrobial and antioxidant activity <i>in vitro</i> of the hydroalcoholic extract of two species of the genus Cyperus (Cyperaceae)

Bezerra, José Jailson Lima; Nascimento, Ticiano Gomes do; Kamiya, Regianne Umeko; Prata, Ana Paula do Nascimento; Medeiros, Patrícia Muniz de; Silva, Sâmia Andrícia Souza da; Melo, Nathaly Esperidião de

doi:10.1590/s2175-97902022e20205

Abstract

Several factors contribute to the resistance of some pathogenic microorganisms and this fact requires the search for new therapeutic alternatives. The genus Cyperus (family Cyperaceae) groups species that present chemical compounds of pharmacological interest, mainly with antimicrobial action. Thus, the present work was carried out to investigate the antimicrobial activities, antioxidants and the phytochemical profile of Cyperus articulatus L. and Cyperus iria L. Hydroalcoholic extracts (1:1, v:v) of the aerial and underground parts of these species were used to analyze the total phenol content and to evaluate the in vitro antioxidant activity against the DPPH (2,2-diphenyl-1-picrylhydrazyl). The ethyl acetate and chloroform phases resulting from liquid-liquid partitioning of C. articulatus and C. iria extracts were evaluated in antimicrobial assays and subject to high performance liquid chromatography (HPLC-DAD) analysis. The chromatograms obtained by HPLC-DAD allowed us to identify four compounds: chlorogenic acid, catechin, quercetin, and quercitrin. The hydroalcoholic extracts of C. articulatus and C. iria showed a weak antioxidant activity with IC₅₀ of 395.57 and 321.33 μg/mL (aerial parts), and 1,114.01 and 436.82 μg/mL (underground parts), respectively. Regarding antimicrobial activity, the chloroform phase of C. iria showed the best result at the concentration of only 31.2 µg/mL against the pathogens Candida albicans and Staphylococcus aureus. The ethyl acetate phases of the aerial parts of C. articulatus and C. iria did not show antimicrobial activity.

Keywords:
Biological activities; Phytochemistry; Medicinal plants; Cyperus articulatus; Cyperus iria

INTRODUCTION

Research using medicinal plants has significantly contributed to the development of new therapeutic strategies based on bioactive compounds (Firmo et al., 2011Firmo WCA, Menezes VDJM, Passos CEC, Dias CN, Alves LPL, Dias ICL, et al. Contexto histórico, uso popular e concepção científica sobre plantas medicinais. Cad Pesq. 2011;18:90-95.). Plant drug use is common in developed and developing countries as homemade medicine, drugs and raw materials for the pharmaceutical industry, and represents a substantial proportion of products traded in the global market (Sivapalan, 2013Sivapalan SR. Medicinal uses and pharmacological activities of Cyperus rotundus Linn-A Review. Int J Sci Res. 2013;3(5):1-8.). There is a growing interest in studies on medicinal plants used in traditional medicine that may be potential sources of new antimicrobial agents (Compean, Yalvez, 2014Compean KL, Ynalvez RA. Antimicrobial activity of plant secondary metabolites: A review. Res J Med Plants. 2014;8(5):204-213.). This is because of the global spread of resistant microorganisms, which have caused a relevant biological risk, influencing our health and the health of the planet (Hernando-Amado et al., 2019Hernando-Amado S, Coque TM, Baquero F, Martínez JL. Defining and combating antibiotic resistance from One Health and Global Health perspectives. Nat microbial. 2019;4(9):1432-1442.). Thus, the demand for natural antimicrobials has increased in recent decades, mainly for natural products extracted from plants that stand out for the potential of alternative treatments to bacterial control using less toxic and more efficient substances against bacterial resistance (Gomes et al., 2018Gomes FMS, Xavier JC, Santos JFS, Matos YMLS, Tintino SR, Freitas TS, et al. Evaluation of antibacterial and modifying action of catechin antibiotics in resistant strains. Microb Pathog. 2018;115:175-178.).

Species belonging to the Cyperaceae family represent an important source of active constituents with therapeutic properties (Gamal, Hani, Sabrin, 2015Gamal MA, Hani KMK, Sabrin IRM. A review: Compounds isolated from Cyperus species (Part II): Terpenoidal. Int J Pharmacogn Phytochem Res. 2015;7(1):83-99.). In taxonomic terms, Cypereae is the second most diverse tribe and its largest genus, Cyperus (Linnaeus 1753:44) includes about 600 species, some of which are used in popular medicine (Larridon et al., 2014Larridon I, Bauters K, Huygh W, Reynders M, Goetghebeur P. Taxonomic changes in C4 Cyperus (Cypereae, Cyperoideae, Cyperaceae): combining the sedge genera Ascolepis, Kyllinga and Pycreus into Cyperus sl. Phytotaxa. 2014;166(1):33-48.; Reid, Carter, Urbatsch, 2014Reid CS, Carter R, Urbatsch LE. Phylogenetic insights into New World Cyperus (Cyperaceae) using nuclear ITS sequences. Brittonia. 2014;66(3)292-305.). The activities antioxidant and antimicrobial of some species of this genus have been widely studied and scientifically proven (Soumaya et al., 2014Soumaya K.J., Zield G, Nouha N, Mounira K, Kamel G, Genviève FDM, et al. Evaluation of in vitro antioxidant and apoptotic activities of Cyperus rotundus. Asian Pac J Trop Med. 2014;7(2)105-112.; Essaidi et al., 2014Essaidi I, Koubaier HBH, Snoussi A, Casabianca H, Chaabouni MM, Bouzouita N. Chemical composition of Cyperus rotundus L. tubers essential oil from the south of Tunisia, antioxidant potentiality and antibacterial activity against foodborne pathogens. J Essent Oil Bear Pl. 2014;17(3):522-532.; Nassar et al., 2015Nassar MI, Yassine YM, Elshamy AI, El-Beih AA, El-Shazly M, Singab ANB. Essential oil and antimicrobial activity of aerial parts of Cyperus leavigatus L.(Family: Cyperaceae). J Essent Oil Bear Plants. 2015;18(2):416-422.; Jing et al., 2016Jing S, Li Q, Zheng L, Yue L, Fan S, Tao G. Dynamic high pressure microfluidization-assisted extraction and bioactivities of Cyperus esculentus (C. esculentus L.) leaves flavonoids. Food chem. 2016;192:319-327.). Such findings have raised the interest of the scientific community to continue the search for new substances for medical applications from the products obtained from Cyperus spp. The specie Cyperus articulatus L. popularly known as “priprioca” has been evaluated for its antibacterial (Oladosu et al., 2011Oladosu IA, Usman LA, Olawore NO, Atata RF. Antibacterial activity of rhizomes essential oils of two types of Cyperus articulatus growing in Nigeria. Adv Biol Res. 2011;5(3):179-183.) and antimicrobial (Azzaz, El-Khateeb, Farag, 2014Azzaz NA, El-Khateeb AY, Farag AA. Chemical composition and biological activity of the essential oil of Cyperus articulatus. Int J Acad Res. 2014;6(5):265-269.).

In addition to C. articulatus, some studies have reported that bioactive compounds identified in C. rotundus are extremely efficient when tested against pathogenic microorganisms (Sharma, Verma, Ramteke, 2014Sharma A, Verma R, Ramteke P. Cyperus rotundus: a potential novel source of therapeutic compound against urinary tract pathogens. J Herb Med. 2014;4(2):74-82.; Singh, Sharma, 2015Singh AP, Sharma SK. A new pentacyclic triterpenoid with antimicrobial activity from the tubers of Cyperus rotundus Linn. Hygeia J D Med. 2015;7(1):1-9.). Regarding phytochemical findings, a wide spectrum of chemical compounds was isolated from the species Cyperus rotundus L. Some examples are: cyperotundol and methoxycyperotundol (Zhou, Yin, 2012Zhou Z, Yin W. Two novel phenolic compounds from the rhizomes of Cyperus rotundus L. Molecules . 2012;17(11):12636-12641.), rotunduside A, B and C (Zhou, Zhang, 2013Zhou Z, Zhang H. Phenolic and iridoid glycosides from the rhizomes of Cyperus rotundus L. Med Chem Res. 2013;22(10):4830-4835.; Zhang et al., 2014Zhang TZ, Xu LJ, Xiao HP, Zhou X, Mo SM, Cai SM, et al. A new iridoid glycoside from the rhizomes of Cyperus rotundus. B Korean Chem Soc. 2014;35(7):2207-2209.), cyperene-3,8-dione, cyperenol, cyperenoic acid, cyperusol C and D, α-rotunol (Xu et al., 2015Xu HB, Ma YB, Huang XY, Geng CA, Wang H, Zhao Y, et al. Bioactivity-guided isolation of anti-hepatitis B virus active sesquiterpenoids from the traditional Chinese medicine: rhizomes of Cyperus rotundus. J Ethnopharmacol . 2015;171:131-140.), cyperusphenol A, B, C and D (Ito et al., 2012Ito T, Endo H, Shinohara H, Oyama M, Akao Y, Iinuma M. Occurrence of stilbene oligomers in Cyperus rhizomes. Fitoterapia. 2012;83(8):1420-1429.), α-cyperone (Jung et al., 2013Jung SH, Kim SJ, Jun BG, Lee KT, Hong SP, Oh MS, et al. α-Cyperone, isolated from the rhizomes of Cyperus rotundus, inhibits LPS-induced COX-2 expression and PGE2 production through the negative regulation of NFκB signalling in RAW 264.7 cells. J Ethnopharmacol. 2013;147(1):208-214.), cyperalin A (Ibrahim et al., 2018Ibrahim SRM, Mohamed GA, Khayat MTA, Zayed MF, El-Kholy AAES. Anti-inflammatory terpenoids from Cyperus rotundus rhizomes. Pak J Pharm Sci. 2018;31(4):1449-1456.) and 14-hydroxy-α-cyperone (Ahn et al., 2015Ahn JH, Lee TW, Kim KH, Byun H, Ryu B, Lee KT, et al. 6-Acetoxy cyperene, a patchoulane-type sesquiterpene isolated from Cyperus rotundus rhizomes induces caspase-dependent apoptosis in human ovarian cancer cells. Phytother Res. 2015;29(9):1330-1338.). In a wide bibliographic review, Peerzada et al. (2015Peerzada AM, Ali HH, Naeem M, Latif M, Bukhari AH, Tanveer A. Cyperus rotundus L.: traditional uses, phytochemistry, and pharmacological activities. J Ethnopharmacol. 2015;174:540-560.) reported that the rhizomes and tubers of C. rotundus contain volatile oils, flavonoids, phenolic acids, coumarins, steroids and iridoid glycosides. Other studies were also conducted with Cyperus esculentus L. where identified the presence of well-known flavonoids such as quercetin and myricetin (Vega-Morales et al., 2019Vega-Morales T, Mateos-Díaz C, Pérez-Machín R, Wiebe J, Gericke NP, Alarcón C, et al. Chemical composition of industrially and laboratory processed Cyperus esculentus rhizomes. Food Chem. 2019;297:124896.).

As reported by some authors, pharmacological and chemical investigations of natural products obtained from plants are essential for the discovery of new therapeutic alternatives (Pereira, Cardoso, 2012Pereira RJ, Cardoso MG. Metabólitos secundários vegetais e benefícios antioxidantes. J Biotec Biodivers. 2012;3(4):146-152.; Silva et al., 2014Silva ICM, Santos WL, Leal ICR, Zoghbi MGB, Feirhmann AC, Cabral VF, et al. Extraction of essential oil from Cyperus articulatus L. var. articulatus (priprioca) with pressurized CO2. J Supercrit Fluids. 2014;88:134-141.). To assist in this process, there are some types of specific approaches that guide the choice of potentially medicinal plants for the evaluation of their chemical constituents. The chemotaxonomic approach, for example, is characterized by the selection of species of a family or genus, for which there is some knowledge about the secondary metabolites of at least one species of the group (Albuquerque, Hanazaki, 2006Albuquerque UP, Hanazaki N. As pesquisas etnodirigidas na descoberta de novos fármacos de interesse médico e farmacêutico: fragilidades e pespectivas. Rev Bras Farmacogn. 2006;16:678-689.; Silva et al., 2013Silva ACO, Santana EF, Saraiva AM, Coutinho FN, Castro RHA, Pisciottano MNC, et al. Which approach is more effective in the selection of plants with antimicrobial activity? Evid Based Complement Alternat Med. 2013:1-9.).

Knowing that the genus Cyperus groups species that may be sources of chemical compounds of pharmaceutical interest, highlighting Cyperus rotundus, which has been widely studied, including with proven activity against pathogenic microorganisms (Aeganathan et al., 2015Aeganathan R, Rayar A, Ilayaraja S, Prabakaran K, Manivannan R. Anti-oxidant, antimicrobial evaluation and GC-MS analysis of Cyperus rotundus L. rhizomes chloroform fraction. Am J Ethnomed. 2015;2(1):14-20.; Dadook, Mehrabian, Irian, 2016Dadook M, Mehrabian S, Irian S. Antimicrobial effect of Cyperus rotundus on multiple drug resistant Pseudomonas aeruginosa strains. J Med Bacteriol. 2016;5(1):15-20.; Zhang et al., 2017Zhang LL, Zhang LF, Hu QP, Hao DL, Xu JG. Chemical composition, antibacterial activity of Cyperus rotundus rhizomes essential oil against Staphylococcus aureus via membrane disruption and apoptosis pathway. Food control. 2017;80:290-296.), it is likely that other species of the same genus also produce compounds with bactericidal and fungicidal action. Thus, the present research aimed to analyze antimicrobial and antioxidant activities and investigate the phytochemicals of Cyperus articulatus L. and Cyperus iria L.

MATERIAL AND METHODS

Botanical material

Cyperus articulatus L. and Cyperus iria L. were collected at the Serra Dois Irmãos, Viçosa, Alagoas, on January, 2018. Exsiccatae of the botanical material were identified by specialist Ana Paula do Nascimento Prata and deposited in the Herbarium of the Institute of the Environment of Alagoas, under the numbers MAC-64297 (C. articulatus) and MAC-64296 (C. iria).

Obtaining and concentrating extracts

Both aerial and underground parts of C. articulatus and C. iria were oven dried at 45°C and pulverized in a knife mill. The extraction was carried out by maceration using 10 g of powder of the species for 200 mL of hydroalcoholic solution (1:1, v/v). The botanical material in the form of hydroalcoholic extract was concentrated on a rotary evaporator at a constant temperature of approximately 60°C until complete evaporation of the solvent (Bezerra et al., 2019Bezerra JJL, Nascimento TG, Kamiya RU, Prata APN, Medeiros PM, Silva SAS, et al. Phytochemical screening, chromatographic profile and evaluation of antimicrobial and antioxidant activities of three species of the Cyperaceae Juss. Family. J Med Plants Res. 2019;13(14):312-320.).

Partitioning of bioactive extracts

In order to carry out the liquid-liquid partitioning process of the crude hydroalcoholic extract of C. articulatus and C. iria, a separation funnel was used according to the methodology proposed by Bezerra et al. (2019Bezerra JJL, Nascimento TG, Kamiya RU, Prata APN, Medeiros PM, Silva SAS, et al. Phytochemical screening, chromatographic profile and evaluation of antimicrobial and antioxidant activities of three species of the Cyperaceae Juss. Family. J Med Plants Res. 2019;13(14):312-320.). A total of 20 mL of ethyl acetate was used for 20 mL of crude extracts of the aerial parts and 20 mL of chloroform for 20 mL of crude extracts of the underground parts. The phases resulting from the partitioning were obtained separately, reserved for the analyses in High Performance Liquid Chromatography (HPLC-DAD) and tested against pathogenic microorganisms.

Total phenols

For the determination of total phenolics, the Folin-Ciocalteu method was used as described by Waterman and Mole (1994Waterman PG, Mole S. Analysis of phenolic plant metabolites. Blackwell Scientific Publications. 1994;38(4):1064.), with some adaptations. Aliquots of the extracts of the aerial parts (AP) and underground parts (UP) of C. articulatus and C. iria at five different concentrations (AP: 50, 70, 90, 110, 130 µg/mL and UP: 300, 500, 700, 900, 1100 µg/mL). Subsequently, 0.25 ml of the Folin-Ciocalteu reagent was added and after 2 minutes, 1 mL of sodium carbonate (Na₂CO₃). The volume of each flask was completed with distilled water. Each solution was left to stand at room temperature protected from light and, precisely after 2 hours, its reading was taken in a spectrophotometer at 760 nm and compared with the standard curve of gallic acid at six concentration points 2, 4, 5, 6, 8 and 10 μg/mL. The equation obtained from the gallic acid standard curve was: y = 0.1024x - 0.0164, where y is the absorbance and x is the concentration; (R² = 0.9775). The total phenolic content was expressed in μg equivalent of gallic acid (EGA/μg) per μg of the extracts of C. articulatus and C. iria, considering their dry extract content (Bezerra et al., 2019Bezerra JJL, Nascimento TG, Kamiya RU, Prata APN, Medeiros PM, Silva SAS, et al. Phytochemical screening, chromatographic profile and evaluation of antimicrobial and antioxidant activities of three species of the Cyperaceae Juss. Family. J Med Plants Res. 2019;13(14):312-320.).

High Performance Liquid Chromatography (HPLC)

The separation of the bioactive compounds was carried out in High Performance Liquid Chromatography (HPLC) with ultraviolet detector (UV) and diode array (DAD), where ethyl acetate and chloroformic phases of C. articulates and C. iria were injected at a flow rate of 0.6 mL/min for 72 minutes using a Jupiter 5u C18 300A reverse phase column as stationary phase and a mixture of methanol, water and 0.1% trifluoroacetic acid as mobile phase, as described by Bezerra et al. (2019Bezerra JJL, Nascimento TG, Kamiya RU, Prata APN, Medeiros PM, Silva SAS, et al. Phytochemical screening, chromatographic profile and evaluation of antimicrobial and antioxidant activities of three species of the Cyperaceae Juss. Family. J Med Plants Res. 2019;13(14):312-320.). Chromatograms were recorded at wavelengths at 254 nm. To identify the substances, an analytical standard was used specifying the retention time obtained from the sample and its respective wavelengths (Table I).

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TABLE I
Standard used for identification of bioactive compounds by high performance liquid chromatography

In vitro antioxidant activity

Free radical scavenging (FRS) by the DPPH method was evaluated following the methodology of Mensor et al. (2001Mensor LL, Menezes FS, Leitão GG, Reis AS, Santos TC, Coube CS, et al. Screnning of Brazilian plant extracts for antioxidant activity by the use of DPPH free radical method. Phytother Res . 2001;15(2):127-130.) with adaptations. To measure the scavenging capacity of the DPPH radical (2,2-diphenyl-1-picrylhydrazyl), 2.0 mL of DPPH solution was inserted into a 5 mL flask. Subsequently, aliquots of the extracts of the aerial parts (AP) and underground parts (UP) of C. articulatus and C. iria were added at six different concentration points (AP: 700, 500, 300, 100, 80, 60 µg/mL and UP: 1400, 1200, 1000, 800, 600, 400 µg/mL). The final volume of the flask was filled with ethanol and after 30 minutes the absorbance was measured at 518 nm. Trolox® was used as a standard reference compound at the following concentrations: 20, 15, 10, 7.5, 5 and 2.5 µg/mL.

The DPPH radical scavenging capacity was calculated according to the equation: Radical scavenging capacity DPPH (%) = 100 - ((ABS sample - ABS white)*100)/ABS control)). Where: ABS Sample = Absorbance of the sample solution in DPPH; ABS Control = Absorbance of reference solution in DPPH and ABS white = Absorbance of sample solution without DPPH. The results concerning the antioxidant activity were expressed by means of the calculation of IC₅₀ (inhibitory concentration), where the equation of the line referring to the absorbance values of the extracts was used, replacing the value of y with 50 to obtain the concentration of the sample with the capacity to reduce 50% of the DPPH radical. Assays were performed in triplicate and the value was expressed as mean ± standard deviation (SD).

In vitro antimicrobial activity

The efficiency of the ethyl acetate and chloroformic phases obtained from C. articulatus and C. iria were tested against the following pathogenic microorganisms: Staphylococcus aureus (Gram-positive bacterium); Pseudomonas aeruginosa (Gram-negative bacterium), and Candida albicans (fungus) (Bezerra et al., 2019Bezerra JJL, Nascimento TG, Kamiya RU, Prata APN, Medeiros PM, Silva SAS, et al. Phytochemical screening, chromatographic profile and evaluation of antimicrobial and antioxidant activities of three species of the Cyperaceae Juss. Family. J Med Plants Res. 2019;13(14):312-320.).

Minimum Inhibitory Concentration (MIC)

The serial microdilution technique was performed in triplicate, following the methodologies described by Sampaio et al. (2009Sampaio FC, Pereira MSV, Dias CS, Costa VCO, Conde NCO, Buzalaf MAR. In vitro antimicrobial activity of Caesalpinia ferrea Martius fruits against oral pathogens. J Ethnopharmacol . 2009;124(2):289-294.), CLSI (2012)CLSI. Methods for Dilution Antimicrobial Susceptibility Tests for Bacteria That Grow Aerobically; Approved Standard - Ninth Edition. CLSI document M07-A9. Clinical and Laboratory Standards Institute, 950 West Valley Road, Suite 2500, Wayne, Pennsylvania 19087, USA, 2012., and Arendrup et al. (2012Arendrup MC, Cuenca-Estrella M, Lass-Flörl C, Hope W. EUCAST-AFST. EUCAST technical note on the EUCAST definitive document EDef 7.2: method for the determination of broth dilution minimum inhibitory concentrations of antifungal agents for yeasts EDef 7.2 (EUCAST-AFST). Clin Microbiol Infec. 2012;18(7):E246-E247.), with modifications. The ethyl acetate and chloroformic phases of the aerial and underground portions of C. articulates and C. iria were diluted in DMSO at 1% in H₂O at 1000 μg/mL. Subsequently, the phases were diluted into 96-well microplates containing 80 μL of Brain Heart Infusion (BHI) medium per well. Inoculations of S. aureus cells ATCC 27664, P. aeruginosa ATCC 25619 or C. albicans ATCC 36802 were standardized using the colony suspension method and the MacFarland 0.5 scale, as described in the protocols of CLSI (2012)CLSI. Methods for Dilution Antimicrobial Susceptibility Tests for Bacteria That Grow Aerobically; Approved Standard - Ninth Edition. CLSI document M07-A9. Clinical and Laboratory Standards Institute, 950 West Valley Road, Suite 2500, Wayne, Pennsylvania 19087, USA, 2012. and Arendrup et al. (2012)Arendrup MC, Cuenca-Estrella M, Lass-Flörl C, Hope W. EUCAST-AFST. EUCAST technical note on the EUCAST definitive document EDef 7.2: method for the determination of broth dilution minimum inhibitory concentrations of antifungal agents for yeasts EDef 7.2 (EUCAST-AFST). Clin Microbiol Infec. 2012;18(7):E246-E247.. At each phase dilution, 20 μl of a microbial suspension containing 106 CFUm-1 of S. aureus ATCC 27664 or P. aeruginosa ATCC 25619 or 105 CFUmL-1 of C. albicans ATCC 36802 were added, thus obtaining the serial dilution, 15.62, 31.25, 62.50, 125, 250, 500, and 1000 μg/mL of the phases, in the final volume of 100 μL per well. As a negative control, the same microbial inocula were used in BHI broth without antimicrobials. The Minimum Inhibitory Concentration (MIC) was determined by spectrophotometry in an Elisa reader at 560-630 nm after 24 hours of incubation in aerophily at 37°C. The MIC was defined as the lowest concentration range of antimicrobial capable of inhibiting 100% of the microbial growth, in relation to the negative control.

Minimum Bactericidal and Fungicidal Concentration (MBC and MFC)

To determine the minimum bactericidal and fungicidal concentration (MBC and MFC), the methodology described by Lubian et al. (2010Lubian CT, Teixeira JM, Lund RG, Nascente PS, Del Pino FAB. Atividade antifúngica do extrato aquoso de Arctium minus (Hill) Bernh.(Asteraceae) sobre espécies orais de Candida. Rev Bras Plantas Med . 2010;12(2):157-162.), with modifications. MBC and MFC were determined from the results obtained from MIC. A 50 µl aliquot of the wells that showed inhibition of the microorganisms was seeded onto the surface of petri dishes containing bromocresol green agar (BCG), mannitol salt agar and cetrimide selective agar for the development of C. albicans, S aureus and P. aeruginosa, respectively. The petri dishes were incubated at 37ºC for 24h. MBC and MFC were determined by the lower concentration of C. articulatus and C. iria phases that did not show bacterial and fungal growth. All tests were performed in triplicate.

Statistical analyzes

Statistical analyzes were performed using GraphPad Prism 5.0 software and Microsoft Excel® 2010 software. A means test was applied to differentiate the phenol content of C. articulatus and C. iria extracts. The comparison between the groups was performed through analysis of variance (ANOVA), considering all results with p below 0.05 using the Tukey test at 5% probability.

RESULTS AND DISCUSSION

Total phenols

The analyses regarding the quantification of the total phenol content of the hydroalcoholic extracts of the C. articulatus and C. iria aerial parts presented phenolic compound concentrations equivalent to 4.830 μg EAG/ μg and 5.027 μg EAG/μg, respectively. Extracts of the underground parts of both species studied presented much lower levels, indicating a significant difference at the 5% probability level by Tukey test when compared with the aerial parts (Figure 1).

FIGURE 1
Total phenol content of the hydroalcoholic extracts of Cyperus articulatus L. and Cyperus iria L.

From data found in the literature, it was evidenced that the highest levels of phenolic compounds in Cyperus rotundus were identified in the extracts obtained from its leaves 136.0 mg 100 g^-1, while concentrations of this species below of 60 mg 100 g^-1 were found in the tuber extracts (Quayyum et al., 2000Quayyum HA, Mallikd AU, Leach M, Gottardo C. Growth inhibitory effects of nutgrass (Cyperus rotundus) on rice (Oryza sativa) seedlings. J Chem Ecol. 2000;26(9):2221-31.). Veber et al. (2015Veber J, Petrini LA, Andrade LB, Siviero J. Determinação dos compostos fenólicos e da capacidade antioxidante de extratos aquosos e etanólicos de Jambolão (Syzygium cumini L.). Rev Bras Plantas Med . 2015;17(2):267-273.) also reported in their work that the 50% hydro-ethanolic extract of Syzygium cumini L. leaves presented the highest results of phenolic compounds at a concentration of 221.03 mg 100 g^-1 in relation to the other types of hydro-ethanolic extracts at 25%, 75% and 95%. According to Storck et al. (2013Storck CR, Nunes GL, Oliveira BB, Basso C. Folhas, talos, cascas e sementes de vegetais: composição nutricional, aproveitamento na alimentação e análise sensorial de preparações. Cienc Rural. 2013;43(3):537-543.), broccoli leaves have a total polyphenol content higher than 137.15 mg 100 g^-1 compared with their stalk 41.40 mg 100 g^-1.

Equal letters indicate that there is no significant difference and different letters indicate that there is significant difference between the groups according to the Tukey test. p value considered significant below 0.05.

High Performance Liquid Chromatography (HPLC)

From the standards used by the HPLC technique, it was not possible to identify the compounds that occur in the ethyl acetate phase of C. articulatus aerial parts (Figure 2). In order to identify unknown substances that occur in the highest intensity peaks of EAFCAAP, further analysis by means of infrared and nuclear magnetic resonance (NMR) techniques is necessary to elucidate the chemical structure of these compounds. The spectrometer-coupled HPLC can also be used to assist in this identification process.

FIGURE 2
Chromatographic profile of the ethyl acetate phase of the aerial parts of Cyperus articulatus L. (EAFCAAP) at 254 nm wavelength.

Through the chromatographic profile of the ethyl acetate phase of C. iria parts, it was possible to separate a polyphenol of pharmacological interest known as catechin (Figure 3). Importantly, chlorogenic acid was another substance separated in the EAFCIAP chromatogram by the techniques used.

FIGURE 3
Chromatographic profile of the ethyl acetate phase of the aerial parts of Cyperus iria L. (EAFCIAP) at 254 nm wavelength.

Regarding catechin, Senger, Schwanke, Gottlieb (2010Senger AEV, Schwanke CHA, Gottlieb MGV. Chá verde (Camellia sinensis) e suas propriedades funcionais nas doenças crônicas não transmissíveis. Sci Med. 2010;20(4):292-300.) point out that the antioxidant activity associated with this substance can prevent oxidative stress-induced cytotoxicity in different tissues. Chlorogenic acid was another separate compound in EAFCIAP, and although its action is not lasting when isolated, it also contributes to the antioxidant activity of plant extracts (Sartori, Costa, Ribeiro, 2014Sartori GV, Costa CN, Ribeiro AB. Conteúdo fenólico e atividade antioxidante de polpas de frutas congeladas. Rev Bras Pesq Alimentos. 2014;5(3):23-29.). These reports found in the literature regarding the antioxidant potential of catechin and chlorogenic acid reinforce that extracts of C. iria aerial parts present bioactive compounds with high free radical scavenging capacity.

According to the chromatographic profile obtained from the chloroform phase of the underground parts of C. articulatus, it was not possible to identify the substances present in the highest intensity peaks (Figure 4). However, in the lowest intensity peaks of the analyzed sample, the compound known as chlorogenic acid was separated.

FIGURE 4
Chromatographic profile of the chloroformic phase of the underground parts of Cyperus articulatus L. (CFCAUP) at 254 nm wavelength.

In addition to the chlorogenic acid separated on the CFCAUP chromatogram, Metuge et al. (2014Metuge JA, Nyongbela KD, Mbah JA, Samje M, Fotso G, Babiaka SB, et al. Anti-Onchocerca activity and phytochemical analysis of an essential oil from Cyperus articulatus L. BMC Complement Altern Med. 2014;14(1)223.) identified more than 80 compounds in the essential oil of C. articulatus rhizomes through analyses performed in gas chromatography coupled with mass spectrometer. The main chemical constituents reported by these authors were: monoterpenes, sesquiterpenes, hydrocarbons, fatty acids and fatty acid derivatives. Isolated secondary metabolites of Cyperus rotundus are widely used for therapeutic purposes, which is one of the most studied species of the genus Cyperus (Peerzada et al., 2015Peerzada AM, Ali HH, Naeem M, Latif M, Bukhari AH, Tanveer A. Cyperus rotundus L.: traditional uses, phytochemistry, and pharmacological activities. J Ethnopharmacol. 2015;174:540-560.; Al-Snafi, 2016Al-Snafi AE. A review on Cyperus rotundus A potential medicinal plant. IOSR J Pharm. 2016;6(7):32-48.). According to Oliveira and Melo (2018Oliveira CRV, Melo DB. Levantamento Fitoquímico da espécie Cyperus rotundus. Rev Diálogos Cienc. 2018;3(40):1-10.), extracts of this plant have flavonoids, tannins, alkaloids, saponins, triterpenes and sterols, except leucoanthocyanidins.

The major compound separated in the chromatogram obtained from the underground chloroform phase of C. iria is quercitrin. This substance is characterized by being a glycoside formed from the flavonoid quercetin that also appeared in the analyzed sample (Figure 5).

FIGURE 5
Chromatographic profile of the chloroformic phase of the underground parts of Cyperus iria L. (CFCIUP) at 254 nm wavelength.

In studies by Vechia et al. (2016Vechia CAD, Morais B, Schonell AP, Diel KAP, Faust C, Menin C, et al. Isolamento químico e validação analítica por cromatografia líquida de alta eficiência de quercitrina em Solidago chilensis Meyen (Asteraceae). Rev Bras Plantas Med . 2016;18(1):288-296.), quercitrin was found to be a major substance identified in hydroalcoholic extracts of aerial parts of the species Solidago chilensis (Asteraceae), and this constituent is identified by chromatographic and spectroscopic methods. Quercitrin-related therapeutic properties have been described by Ballester et al. (2006Ballester I, Camuesco D, Gálvez J, Medina FS, Zarzuelo A. Flavonoides y enfermedad inflamatoria intestinal. Ars Pharm. 2006;47(1):5-21.), demonstrating that this substance was able to completely restore intestinal hydroelectrolytic transport, which resulted in a reduction in the incidence of diarrhea, one of the symptoms that characterizes intestinal inflammation.

According to Jiménez, Martínez, Fonseca (2009Jiménez CIE, Martínez EYC, Fonseca JG. Flavonoides y sus acciones antioxidantes. Rev Fac Med UNAM. 2009;52(2)73-5.), quercetin is a flavonoid that meets the ideal requirements for effective antioxidant function because its potential is five times greater than vitamins C and E. Antimicrobial activity is another benefit associated with quercetin. Camargo and Raddi (2008Camargo MS, Raddi MSG. Efeito da quercetina sobre o crescimento e atividade hemolítica de Staphylococcus aureus. Rev Eletronica Farm. 2008;5(3):71-78.) reported that 120 µg/mL of this flavonoid demonstrated 70% inhibition of S. aureus growth compared with control.

In vitro antioxidant activity

Based on the IC₅₀ values obtained from antioxidant activity, which expresses the amount of drug needed to reduce the initial DPPH concentration by 50% (Lôbo et al., 2010Lôbo KMS, Athayde ACR, Silva AMA, Rodrigues FFG, Lôbo IS, Bezerra DAC, et al. Avaliação da atividade antibacteriana e prospecção fitoquímica de Solanum paniculatum Lam. e Operculina hamiltonii (G. Don) DF Austin & Staples, do semi-árido paraibano. Rev Bras Plantas Med. 2010;12(2):227-235.), it was evidenced that Trolox® had the best results compared with the samples of the analyzed extracts, requiring a concentration of only 1.8 μg/mL for the scavenging activity of DPPH radicals to occur. These results were expected as Trolox® is widely used as a reference standard for in vitro antioxidant testing (Chaudhuri et al., 2012Chaudhuri D, Ghate NB, Sarkar R, Mandal N. Phytochemical analysis and evaluation of antioxidant and free radical scavenging activity of Withania somnifera root. Asian J Pharm Clin Res. 2012;5(4):193-199.; Felhi et al., 2017Felhi S, Daoud A, Hajlaoui H, Mnafgui K, Gharsallah N, Kadri A. Solvent extraction effects on phytochemical constituents profiles, antioxidant and antimicrobial activities and functional group analysis of Ecballium elaterium seeds and peels fruits. Food Sci Technol. 2017;37(3):483-492.; Jaradat et al., 2017Jaradat NA, Al-Masri M, Zaid NA, Hussein F, Al-Rimawi F, Mokh AA, et al. Phytochemical, antimicrobial and antioxidant preliminary screening of a traditional Palestinian medicinal plant, Ononis pubescens L. Eur J Integr Med. 2017;14:46-51.).

Regarding the evaluation of samples of hydroalcoholic extracts of the aerial parts of C. articulatus and C. iria, the antioxidant activity was verified at concentrations of 395.57 μg/mL and 321.33 μg/mL, respectively. The extracts of the underground parts of the two species studied presented values above 400 μg/mL for the same reduction of the DPPH radical and, therefore, showed an antioxidant activity lower than the aerial parts (Table II). Forero-Doria et al. (2014Forero-Doria O, Astudillo L, Castro RI, Lozano R, Díaz O, Guzman-Jofre L, et al. Antioxidant activity of bioactive extracts obtained from rhizomes of Cyperus digitatus Roxb. Bol Latinoam Caribe Plantas Med Aromát. 2014;13(4):344-350.) also elucidated antioxidant properties in Cyperus digitatus Roxb. indicating that the extracts of this plant may be useful in preventing the progress of various oxidative stress related disorders.

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TABLE II
In vitro antioxidant activity of the hydroalcoholic extracts of Cyperus articulatus L. and Cyperus iria L.

It is likely that the antioxidant activity of C. articulatus and C. iria extracts head-on the DPPH radical is related to the high phenol content identified in the aerial parts of these species, as previously observed in Figure 1. According to Abrahão et al. (2010Abrahão AS, Pereira RGFA, Duarte SMDS, Lima AR, Alvarenga DJ, Ferreira EB. Compostos bioativos e atividade antioxidante do café (Coffea arabica L.). Cienc Agrotec. 2010;34(2):414-420.), the free radical scavenging capacity associated with phenolic compounds is mainly due to their reducing properties and chemical structure. Regarding flavonoids, the most studied group among phenolic compounds, Almeida et al. (2010Almeida MCS, Alves LA, Souza LGS, Machado LL, Matos MC, Oliveira MCF, et al. Flavonoides e outras substâncias de Lippia sidoides e suas atividades antioxidantes. Quim Nova. 2010;33(9):1877-1881.) explain that the antioxidant effects of these substances are attributed to the ability to capture and neutralize oxidizing species such as superoxide anion (O₂), hydroxyl radical or peroxide radical, acting by synergism with other antioxidants such as vitamins C and E (Simões, Almeida, 2015Simões RC, Almeida SSMS. Estudo fitoquímico de Bauhinia forficata (Fabaceae). Biota Amazônia. 2015;5(1):27-31.).

Lee and Park (2019Lee KS, Park SN. Cytoprotective effects and mechanisms of quercetin, quercitrin and avicularin isolated from Lespedeza cuneata G. Don against ROS-induced cellular damage. J Ind Eng Chem. 2019;71:160-166.) evidenced that quercetin was more effective than quercitrin and avicularin in terms of DPPH free radical scavenging capacity, reactive oxygen species (ROS) scavenging capacity, and constant rate of ¹O₂ extinction. According to Li et al. (2016Li X, Jiang Q, Wang T, Liu J, Chen D. Comparison of the antioxidant effects of quercitrin and isoquercitrin: Understanding the role of the 6″-OH group. Molecules. 2016;21(9):1246.), a DPPH elimination assay confirmed that quercitrin and isoquercitrin could efficiently eliminate DPPH radicals. This result implies that quercitrin and isoquercitrin exert antioxidant activities when subjected to direct reactions for the elimination of radicals. Chlorogenic acid, a compound also identified in the aerial and underground parts of C. articulatus and C. iria, has promising antioxidant properties. Santana-Gálvez, Cisneros-Zevallos, Jacobo-Velázquez (2017Santana-Gálvez J, Cisneros-Zevallos L, Jacobo-Velázquez DA. Chlorogenic acid: Recent advances on its dual role as a food additive and a nutraceutical against metabolic syndrome. Molecules . 2017;22(3):358.) reported that this compound can be a basis substance for food preservation, particularly for the inhibition of lipid oxidation.

In vitro antimicrobial activity

Comparing the results regarding microdilution of the ethyl acetate phases of the aerial parts of the studied species, it was found that only C. articulatus showed inhibitory activity against Staphylococcus aureus at MIC of 125 µg/mL (Table III). Oladosu et al. (2011Oladosu IA, Usman LA, Olawore NO, Atata RF. Antibacterial activity of rhizomes essential oils of two types of Cyperus articulatus growing in Nigeria. Adv Biol Res. 2011;5(3):179-183.) suggested in their study that C. articulatus essential oils can be used in formulations for the development of antimicrobial drugs. According to these authors, the determination of the minimum inhibitory concentration using the agar oil dilution method presented MIC of 14 µg/mL for S. aureus and 10 µg/mL for P. aeruginosa. In a preliminary antibacterial screening performed by Kilani-Jaziri et al. (2011Kilani-Jaziri S, Bhouri W, Skandrani I, Limem I, Chekir-Ghedira L, Ghedira K. Phytochemical, antimicrobial, antioxidant and antigenotoxic potentials of Cyperus rotundus extracts. S Afr J Bot. 2011;77(3):767-776.), ethyl acetate extract from Cyperus rotundus was shown to be effective against Staphylococcus aureus, Escherichia coli, Salmonella typhimurium, Salmonella enteritidis and Enterococcus faecalis at MIC of 2.5 mg/mL. Antibacterial activity regarding C. rotundus was also highlighted by Singh and Sharma (2015Singh AP, Sharma SK. A new pentacyclic triterpenoid with antimicrobial activity from the tubers of Cyperus rotundus Linn. Hygeia J D Med. 2015;7(1):1-9.).

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TABLE III
Determination of Minimum Inhibitory Concentration (MIC) and Minimum Bactericidal and Fungicidal Concentration (MBC and MFC) of the ethyl acetate and chloroform phases of the aerial and underground parts of Cyperus articulatus L. and Cyperus iria L.

The best MIC and MFC results were evidenced in CFCIUP. This chloroform phase showed bacteriostatic and fungistatic effects against Candida albicans and Staphylococcus aureus pathogens, inhibiting the growth of these microorganisms in the MIC of 31.2 µg/mL. For MFC, a concentration of only 31.2 µg/mL was also required to induce the fungicidal effect on C. albicans yeast. All these data indicate that C. iria underground parts can be an important source of natural products, such as quercetin, a compound identified in high performance liquid chromatography assays (Figure 5), which has a broad spectrum of activity against pathogenic microorganisms (Camargo, Raddi, 2008Camargo MS, Raddi MSG. Efeito da quercetina sobre o crescimento e atividade hemolítica de Staphylococcus aureus. Rev Eletronica Farm. 2008;5(3):71-78.). In a phytochemical study by Kishore and Alluraiah (2013Kishore G, Alluraiah G. Phytochemical screening and antimicrobial assessment of Cyperus iria (L) weeds roots. Bull Pharm Med Sci. 2013;1(2):151-156.), it was possible to evidence the presence of bioactive compounds such as anthraquinones, flavonoids, steroids and phenols in C. iria, which have efficient properties in the treatment of microbial diseases. Antifungal activity evaluations of alkaloids extracted from C. iria were performed by Zhou et al. (2010Zhou B, Zeng J, Yan X, Jiang P, Liu G. Phytoactivity and antifungal activity of total alkaloids from stem of Cyperus iria. J Trop Subtrop Bot. 2010;18(3):304-309.), the authors pointed out that these compounds have been shown to be effective against the tested microorganisms.

Gram-negative bacterium Pseudomonas aeruginosa showed greater resistance to the chloroform phases of the underground parts of C. articulatus and C. iria, requiring MIC and MBC of 250 µg/mL for the bacteriostatic and bactericidal effect of this pathogen to occur. In a study by Bezerra et al. (2019Bezerra JJL, Nascimento TG, Kamiya RU, Prata APN, Medeiros PM, Silva SAS, et al. Phytochemical screening, chromatographic profile and evaluation of antimicrobial and antioxidant activities of three species of the Cyperaceae Juss. Family. J Med Plants Res. 2019;13(14):312-320.), the chloroform phases of the underground parts of Kyllinga odorata Vahl and Oxycaryum cubensis Poepp. & Kunth were responsible for inhibiting this Gram-negative bacterium at the minimum inhibitory concentrations of 500 µg/mL and 62.5 µg/mL, respectively. According to Kobayashi, Sadoyama, Vieira (2009Kobayashi CCBA, Sadoyama G, Vieira JDG. Determinação da resistência antimicrobiana associada em isolados clínicos de Staphylococcus aureus e Pseudomonas aeruginosa em um hospital público de Goiânia, Estado de Goiás. Rev Soc Bras Med Trop. 2009;42(4):404-410.), resistance conferred by P. aeruginosa presumes the difficulty of establishing which antimicrobial combination options for the treatment of severe infections caused by this pathogen. Figueiredo et al. (2007Figueiredo EAP, Ramos H, Maciel MAV, Vilar MDCM, Loureiro NG, Pereira RG. Pseudomonas aeruginosa: frequency of resistance to multiple drugs and cross-resistance between antimicrobials in Recife/PE. Rev Bras Terapia Intensiva. 2007;19(4):421-427.) also state that P. aeruginosa is a multi-drug resistant Gram-negative bacterium.

Chlorogenic acid, a substance identified in the aerial and underground parts of C. articulatus and C. iria, has been reported in the literature as having activity against a wide range of microorganisms, including bacteria, yeasts, fungi, viruses, and amoebas (Santana-Gálvez, Cisneros-Zevallos, Jacobo-Velázquez, 2017Santana-Gálvez J, Cisneros-Zevallos L, Jacobo-Velázquez DA. Chlorogenic acid: Recent advances on its dual role as a food additive and a nutraceutical against metabolic syndrome. Molecules . 2017;22(3):358.). These antimicrobial properties can be useful for the food industry in its constant search for new, natural molecules for the preservation of food products (Santana-Gálvez, Cisneros-Zevallos, Jacobo-Velázquez, 2017Santana-Gálvez J, Cisneros-Zevallos L, Jacobo-Velázquez DA. Chlorogenic acid: Recent advances on its dual role as a food additive and a nutraceutical against metabolic syndrome. Molecules . 2017;22(3):358.). Su et al. (2019Su M, Liu F, Luo Z, Wu H, Zhang X, Wang D, et al. The antibacterial activity and mechanism of chlorogenic acid against foodborne pathogen Pseudomonas aeruginosa. Foodborne Pathog Dis. 2019;16(12):823-830.) reported that chlorogenic acid increased the permeability of the intracellular membrane and induced the exfoliation of the outer membrane in P. aeruginosa. Thus, damages to intracellular and external membranes, as well as disruption of cellular metabolism, resulted in death. In addition to chlorogenic acid, a study on quercetin showed a broad-spectrum antibacterial activity against bacterial pathogens. According to Gopikrishnan et al. (2017Gopikrishnan V, Radhakrishnan M, Pazhanimurugan R, Shanmugasundaram T, Balagurunathan R. Antimicrobial, antitubercular and antiproliferative activities of quercetin isolated from the marine Streptomyces fradiae. Bangladesh J Pharmacol. 2017;12(3):333-334.), quercetin inhibited gram-positive bacteria at a concentration of 6.3 µg/mL, considering that the MIC for gram-negative bacteria varies between 12.5 and 50.0 µg/mL.

CONCLUSION

Cyperus articulatus and Cyperus iria presented chemical compounds of great pharmacological importance, such as: chlorogenic acid, catechin, quercetin and quercitrin. The hydroalcoholic extracts of the aerial and underground parts of both species showed low antioxidant activity by the DPPH method. The chloroform phases of the underground parts of C. articulatus and C. iria showed inhibitory activity when tested against C. albicans, S. aureus and P. aeruginosa, indicating that the studied species are sources of antibacterial and antifungal compounds.

ACKNOWLEDGEMENTS

We thank to the Programa de Pós-Graduação em Agronomia (Produção Vegetal) of the Universidade Federal de Alagoas (UFAL) for the support for the development of this research.

REFERENCES

Abrahão AS, Pereira RGFA, Duarte SMDS, Lima AR, Alvarenga DJ, Ferreira EB. Compostos bioativos e atividade antioxidante do café (Coffea arabica L.). Cienc Agrotec. 2010;34(2):414-420.
Aeganathan R, Rayar A, Ilayaraja S, Prabakaran K, Manivannan R. Anti-oxidant, antimicrobial evaluation and GC-MS analysis of Cyperus rotundus L. rhizomes chloroform fraction. Am J Ethnomed. 2015;2(1):14-20.
Ahn JH, Lee TW, Kim KH, Byun H, Ryu B, Lee KT, et al. 6-Acetoxy cyperene, a patchoulane-type sesquiterpene isolated from Cyperus rotundus rhizomes induces caspase-dependent apoptosis in human ovarian cancer cells. Phytother Res. 2015;29(9):1330-1338.
Albuquerque UP, Hanazaki N. As pesquisas etnodirigidas na descoberta de novos fármacos de interesse médico e farmacêutico: fragilidades e pespectivas. Rev Bras Farmacogn. 2006;16:678-689.
Al-Snafi AE. A review on Cyperus rotundus A potential medicinal plant. IOSR J Pharm. 2016;6(7):32-48.
Almeida MCS, Alves LA, Souza LGS, Machado LL, Matos MC, Oliveira MCF, et al. Flavonoides e outras substâncias de Lippia sidoides e suas atividades antioxidantes. Quim Nova. 2010;33(9):1877-1881.
Arendrup MC, Cuenca-Estrella M, Lass-Flörl C, Hope W. EUCAST-AFST. EUCAST technical note on the EUCAST definitive document EDef 7.2: method for the determination of broth dilution minimum inhibitory concentrations of antifungal agents for yeasts EDef 7.2 (EUCAST-AFST). Clin Microbiol Infec. 2012;18(7):E246-E247.
Azzaz NA, El-Khateeb AY, Farag AA. Chemical composition and biological activity of the essential oil of Cyperus articulatus Int J Acad Res. 2014;6(5):265-269.
Ballester I, Camuesco D, Gálvez J, Medina FS, Zarzuelo A. Flavonoides y enfermedad inflamatoria intestinal. Ars Pharm. 2006;47(1):5-21.
Bezerra JJL, Nascimento TG, Kamiya RU, Prata APN, Medeiros PM, Silva SAS, et al. Phytochemical screening, chromatographic profile and evaluation of antimicrobial and antioxidant activities of three species of the Cyperaceae Juss. Family. J Med Plants Res. 2019;13(14):312-320.
Camargo MS, Raddi MSG. Efeito da quercetina sobre o crescimento e atividade hemolítica de Staphylococcus aureus Rev Eletronica Farm. 2008;5(3):71-78.
Chaudhuri D, Ghate NB, Sarkar R, Mandal N. Phytochemical analysis and evaluation of antioxidant and free radical scavenging activity of Withania somnifera root. Asian J Pharm Clin Res. 2012;5(4):193-199.
CLSI. Methods for Dilution Antimicrobial Susceptibility Tests for Bacteria That Grow Aerobically; Approved Standard - Ninth Edition. CLSI document M07-A9. Clinical and Laboratory Standards Institute, 950 West Valley Road, Suite 2500, Wayne, Pennsylvania 19087, USA, 2012.
Compean KL, Ynalvez RA. Antimicrobial activity of plant secondary metabolites: A review. Res J Med Plants. 2014;8(5):204-213.
Dadook M, Mehrabian S, Irian S. Antimicrobial effect of Cyperus rotundus on multiple drug resistant Pseudomonas aeruginosa strains. J Med Bacteriol. 2016;5(1):15-20.
Essaidi I, Koubaier HBH, Snoussi A, Casabianca H, Chaabouni MM, Bouzouita N. Chemical composition of Cyperus rotundus L. tubers essential oil from the south of Tunisia, antioxidant potentiality and antibacterial activity against foodborne pathogens. J Essent Oil Bear Pl. 2014;17(3):522-532.
Felhi S, Daoud A, Hajlaoui H, Mnafgui K, Gharsallah N, Kadri A. Solvent extraction effects on phytochemical constituents profiles, antioxidant and antimicrobial activities and functional group analysis of Ecballium elaterium seeds and peels fruits. Food Sci Technol. 2017;37(3):483-492.
Figueiredo EAP, Ramos H, Maciel MAV, Vilar MDCM, Loureiro NG, Pereira RG. Pseudomonas aeruginosa: frequency of resistance to multiple drugs and cross-resistance between antimicrobials in Recife/PE. Rev Bras Terapia Intensiva. 2007;19(4):421-427.
Firmo WCA, Menezes VDJM, Passos CEC, Dias CN, Alves LPL, Dias ICL, et al. Contexto histórico, uso popular e concepção científica sobre plantas medicinais. Cad Pesq. 2011;18:90-95.
Forero-Doria O, Astudillo L, Castro RI, Lozano R, Díaz O, Guzman-Jofre L, et al. Antioxidant activity of bioactive extracts obtained from rhizomes of Cyperus digitatus Roxb. Bol Latinoam Caribe Plantas Med Aromát. 2014;13(4):344-350.
Gamal MA, Hani KMK, Sabrin IRM. A review: Compounds isolated from Cyperus species (Part II): Terpenoidal. Int J Pharmacogn Phytochem Res. 2015;7(1):83-99.
Gomes FMS, Xavier JC, Santos JFS, Matos YMLS, Tintino SR, Freitas TS, et al. Evaluation of antibacterial and modifying action of catechin antibiotics in resistant strains. Microb Pathog. 2018;115:175-178.
Gopikrishnan V, Radhakrishnan M, Pazhanimurugan R, Shanmugasundaram T, Balagurunathan R. Antimicrobial, antitubercular and antiproliferative activities of quercetin isolated from the marine Streptomyces fradiae Bangladesh J Pharmacol. 2017;12(3):333-334.
Hernando-Amado S, Coque TM, Baquero F, Martínez JL. Defining and combating antibiotic resistance from One Health and Global Health perspectives. Nat microbial. 2019;4(9):1432-1442.
Ibrahim SRM, Mohamed GA, Khayat MTA, Zayed MF, El-Kholy AAES. Anti-inflammatory terpenoids from Cyperus rotundus rhizomes. Pak J Pharm Sci. 2018;31(4):1449-1456.
Ito T, Endo H, Shinohara H, Oyama M, Akao Y, Iinuma M. Occurrence of stilbene oligomers in Cyperus rhizomes. Fitoterapia. 2012;83(8):1420-1429.
Jaradat NA, Al-Masri M, Zaid NA, Hussein F, Al-Rimawi F, Mokh AA, et al. Phytochemical, antimicrobial and antioxidant preliminary screening of a traditional Palestinian medicinal plant, Ononis pubescens L. Eur J Integr Med. 2017;14:46-51.
Jiménez CIE, Martínez EYC, Fonseca JG. Flavonoides y sus acciones antioxidantes. Rev Fac Med UNAM. 2009;52(2)73-5.
Jing S, Li Q, Zheng L, Yue L, Fan S, Tao G. Dynamic high pressure microfluidization-assisted extraction and bioactivities of Cyperus esculentus (C. esculentus L.) leaves flavonoids. Food chem. 2016;192:319-327.
Jung SH, Kim SJ, Jun BG, Lee KT, Hong SP, Oh MS, et al. α-Cyperone, isolated from the rhizomes of Cyperus rotundus, inhibits LPS-induced COX-2 expression and PGE2 production through the negative regulation of NFκB signalling in RAW 264.7 cells. J Ethnopharmacol. 2013;147(1):208-214.
Kilani-Jaziri S, Bhouri W, Skandrani I, Limem I, Chekir-Ghedira L, Ghedira K. Phytochemical, antimicrobial, antioxidant and antigenotoxic potentials of Cyperus rotundus extracts. S Afr J Bot. 2011;77(3):767-776.
Kishore G, Alluraiah G. Phytochemical screening and antimicrobial assessment of Cyperus iria (L) weeds roots. Bull Pharm Med Sci. 2013;1(2):151-156.
Kobayashi CCBA, Sadoyama G, Vieira JDG. Determinação da resistência antimicrobiana associada em isolados clínicos de Staphylococcus aureus e Pseudomonas aeruginosa em um hospital público de Goiânia, Estado de Goiás. Rev Soc Bras Med Trop. 2009;42(4):404-410.
Larridon I, Bauters K, Huygh W, Reynders M, Goetghebeur P. Taxonomic changes in C4 Cyperus (Cypereae, Cyperoideae, Cyperaceae): combining the sedge genera Ascolepis, Kyllinga and Pycreus into Cyperus sl. Phytotaxa. 2014;166(1):33-48.
Lee KS, Park SN. Cytoprotective effects and mechanisms of quercetin, quercitrin and avicularin isolated from Lespedeza cuneata G. Don against ROS-induced cellular damage. J Ind Eng Chem. 2019;71:160-166.
Li X, Jiang Q, Wang T, Liu J, Chen D. Comparison of the antioxidant effects of quercitrin and isoquercitrin: Understanding the role of the 6″-OH group. Molecules. 2016;21(9):1246.
Lôbo KMS, Athayde ACR, Silva AMA, Rodrigues FFG, Lôbo IS, Bezerra DAC, et al. Avaliação da atividade antibacteriana e prospecção fitoquímica de Solanum paniculatum Lam. e Operculina hamiltonii (G. Don) DF Austin & Staples, do semi-árido paraibano. Rev Bras Plantas Med. 2010;12(2):227-235.
Lubian CT, Teixeira JM, Lund RG, Nascente PS, Del Pino FAB. Atividade antifúngica do extrato aquoso de Arctium minus (Hill) Bernh.(Asteraceae) sobre espécies orais de Candida Rev Bras Plantas Med . 2010;12(2):157-162.
Mensor LL, Menezes FS, Leitão GG, Reis AS, Santos TC, Coube CS, et al. Screnning of Brazilian plant extracts for antioxidant activity by the use of DPPH free radical method. Phytother Res . 2001;15(2):127-130.
Metuge JA, Nyongbela KD, Mbah JA, Samje M, Fotso G, Babiaka SB, et al. Anti-Onchocerca activity and phytochemical analysis of an essential oil from Cyperus articulatus L. BMC Complement Altern Med. 2014;14(1)223.
Nassar MI, Yassine YM, Elshamy AI, El-Beih AA, El-Shazly M, Singab ANB. Essential oil and antimicrobial activity of aerial parts of Cyperus leavigatus L.(Family: Cyperaceae). J Essent Oil Bear Plants. 2015;18(2):416-422.
Oladosu IA, Usman LA, Olawore NO, Atata RF. Antibacterial activity of rhizomes essential oils of two types of Cyperus articulatus growing in Nigeria. Adv Biol Res. 2011;5(3):179-183.
Oliveira CRV, Melo DB. Levantamento Fitoquímico da espécie Cyperus rotundus Rev Diálogos Cienc. 2018;3(40):1-10.
Peerzada AM, Ali HH, Naeem M, Latif M, Bukhari AH, Tanveer A. Cyperus rotundus L.: traditional uses, phytochemistry, and pharmacological activities. J Ethnopharmacol. 2015;174:540-560.
Pereira RJ, Cardoso MG. Metabólitos secundários vegetais e benefícios antioxidantes. J Biotec Biodivers. 2012;3(4):146-152.
Quayyum HA, Mallikd AU, Leach M, Gottardo C. Growth inhibitory effects of nutgrass (Cyperus rotundus) on rice (Oryza sativa) seedlings. J Chem Ecol. 2000;26(9):2221-31.
Reid CS, Carter R, Urbatsch LE. Phylogenetic insights into New World Cyperus (Cyperaceae) using nuclear ITS sequences. Brittonia. 2014;66(3)292-305.
Sampaio FC, Pereira MSV, Dias CS, Costa VCO, Conde NCO, Buzalaf MAR. In vitro antimicrobial activity of Caesalpinia ferrea Martius fruits against oral pathogens. J Ethnopharmacol . 2009;124(2):289-294.
Santana-Gálvez J, Cisneros-Zevallos L, Jacobo-Velázquez DA. Chlorogenic acid: Recent advances on its dual role as a food additive and a nutraceutical against metabolic syndrome. Molecules . 2017;22(3):358.
Sartori GV, Costa CN, Ribeiro AB. Conteúdo fenólico e atividade antioxidante de polpas de frutas congeladas. Rev Bras Pesq Alimentos. 2014;5(3):23-29.
Senger AEV, Schwanke CHA, Gottlieb MGV. Chá verde (Camellia sinensis) e suas propriedades funcionais nas doenças crônicas não transmissíveis. Sci Med. 2010;20(4):292-300.
Sharma A, Verma R, Ramteke P. Cyperus rotundus: a potential novel source of therapeutic compound against urinary tract pathogens. J Herb Med. 2014;4(2):74-82.
Simões RC, Almeida SSMS. Estudo fitoquímico de Bauhinia forficata (Fabaceae). Biota Amazônia. 2015;5(1):27-31.
Silva ACO, Santana EF, Saraiva AM, Coutinho FN, Castro RHA, Pisciottano MNC, et al. Which approach is more effective in the selection of plants with antimicrobial activity? Evid Based Complement Alternat Med. 2013:1-9.
Silva ICM, Santos WL, Leal ICR, Zoghbi MGB, Feirhmann AC, Cabral VF, et al. Extraction of essential oil from Cyperus articulatus L. var. articulatus (priprioca) with pressurized CO2. J Supercrit Fluids. 2014;88:134-141.
Singh AP, Sharma SK. A new pentacyclic triterpenoid with antimicrobial activity from the tubers of Cyperus rotundus Linn. Hygeia J D Med. 2015;7(1):1-9.
Sivapalan SR. Medicinal uses and pharmacological activities of Cyperus rotundus Linn-A Review. Int J Sci Res. 2013;3(5):1-8.
Soumaya K.J., Zield G, Nouha N, Mounira K, Kamel G, Genviève FDM, et al. Evaluation of in vitro antioxidant and apoptotic activities of Cyperus rotundus Asian Pac J Trop Med. 2014;7(2)105-112.
Storck CR, Nunes GL, Oliveira BB, Basso C. Folhas, talos, cascas e sementes de vegetais: composição nutricional, aproveitamento na alimentação e análise sensorial de preparações. Cienc Rural. 2013;43(3):537-543.
Su M, Liu F, Luo Z, Wu H, Zhang X, Wang D, et al. The antibacterial activity and mechanism of chlorogenic acid against foodborne pathogen Pseudomonas aeruginosa Foodborne Pathog Dis. 2019;16(12):823-830.
Veber J, Petrini LA, Andrade LB, Siviero J. Determinação dos compostos fenólicos e da capacidade antioxidante de extratos aquosos e etanólicos de Jambolão (Syzygium cumini L.). Rev Bras Plantas Med . 2015;17(2):267-273.
Vechia CAD, Morais B, Schonell AP, Diel KAP, Faust C, Menin C, et al. Isolamento químico e validação analítica por cromatografia líquida de alta eficiência de quercitrina em Solidago chilensis Meyen (Asteraceae). Rev Bras Plantas Med . 2016;18(1):288-296.
Vega-Morales T, Mateos-Díaz C, Pérez-Machín R, Wiebe J, Gericke NP, Alarcón C, et al. Chemical composition of industrially and laboratory processed Cyperus esculentus rhizomes. Food Chem. 2019;297:124896.
Xu HB, Ma YB, Huang XY, Geng CA, Wang H, Zhao Y, et al. Bioactivity-guided isolation of anti-hepatitis B virus active sesquiterpenoids from the traditional Chinese medicine: rhizomes of Cyperus rotundus J Ethnopharmacol . 2015;171:131-140.
Waterman PG, Mole S. Analysis of phenolic plant metabolites. Blackwell Scientific Publications. 1994;38(4):1064.
Zhang TZ, Xu LJ, Xiao HP, Zhou X, Mo SM, Cai SM, et al. A new iridoid glycoside from the rhizomes of Cyperus rotundus B Korean Chem Soc. 2014;35(7):2207-2209.
Zhang LL, Zhang LF, Hu QP, Hao DL, Xu JG. Chemical composition, antibacterial activity of Cyperus rotundus rhizomes essential oil against Staphylococcus aureus via membrane disruption and apoptosis pathway. Food control. 2017;80:290-296.
Zhou B, Zeng J, Yan X, Jiang P, Liu G. Phytoactivity and antifungal activity of total alkaloids from stem of Cyperus iria J Trop Subtrop Bot. 2010;18(3):304-309.
Zhou Z, Yin W. Two novel phenolic compounds from the rhizomes of Cyperus rotundus L. Molecules . 2012;17(11):12636-12641.
Zhou Z, Zhang H. Phenolic and iridoid glycosides from the rhizomes of Cyperus rotundus L. Med Chem Res. 2013;22(10):4830-4835.

FUNDING

This work was carried out with the support of the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brazil (CAPES) - Financing Code 001.

Publication Dates

Publication in this collection
07 Nov 2022
Date of issue
2022

History

Received
20 Mar 2020
Accepted
30 July 2020

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Abrahão AS, Pereira RGFA, Duarte SMDS, Lima AR, Alvarenga DJ, Ferreira EB. Compostos bioativos e atividade antioxidante do café (Coffea arabica L.). Cienc Agrotec. 2010;34(2):414-420.

[2] Aeganathan R, Rayar A, Ilayaraja S, Prabakaran K, Manivannan R. Anti-oxidant, antimicrobial evaluation and GC-MS analysis of Cyperus rotundus L. rhizomes chloroform fraction. Am J Ethnomed. 2015;2(1):14-20.

[3] Ahn JH, Lee TW, Kim KH, Byun H, Ryu B, Lee KT, et al. 6-Acetoxy cyperene, a patchoulane-type sesquiterpene isolated from Cyperus rotundus rhizomes induces caspase-dependent apoptosis in human ovarian cancer cells. Phytother Res. 2015;29(9):1330-1338.

[4] Albuquerque UP, Hanazaki N. As pesquisas etnodirigidas na descoberta de novos fármacos de interesse médico e farmacêutico: fragilidades e pespectivas. Rev Bras Farmacogn. 2006;16:678-689.

[5] Al-Snafi AE. A review on Cyperus rotundus A potential medicinal plant. IOSR J Pharm. 2016;6(7):32-48.

[6] Almeida MCS, Alves LA, Souza LGS, Machado LL, Matos MC, Oliveira MCF, et al. Flavonoides e outras substâncias de Lippia sidoides e suas atividades antioxidantes. Quim Nova. 2010;33(9):1877-1881.

[7] Arendrup MC, Cuenca-Estrella M, Lass-Flörl C, Hope W. EUCAST-AFST. EUCAST technical note on the EUCAST definitive document EDef 7.2: method for the determination of broth dilution minimum inhibitory concentrations of antifungal agents for yeasts EDef 7.2 (EUCAST-AFST). Clin Microbiol Infec. 2012;18(7):E246-E247.

[8] Azzaz NA, El-Khateeb AY, Farag AA. Chemical composition and biological activity of the essential oil of Cyperus articulatus Int J Acad Res. 2014;6(5):265-269.

[9] Ballester I, Camuesco D, Gálvez J, Medina FS, Zarzuelo A. Flavonoides y enfermedad inflamatoria intestinal. Ars Pharm. 2006;47(1):5-21.

[10] Bezerra JJL, Nascimento TG, Kamiya RU, Prata APN, Medeiros PM, Silva SAS, et al. Phytochemical screening, chromatographic profile and evaluation of antimicrobial and antioxidant activities of three species of the Cyperaceae Juss. Family. J Med Plants Res. 2019;13(14):312-320.

[11] Camargo MS, Raddi MSG. Efeito da quercetina sobre o crescimento e atividade hemolítica de Staphylococcus aureus Rev Eletronica Farm. 2008;5(3):71-78.

[12] Chaudhuri D, Ghate NB, Sarkar R, Mandal N. Phytochemical analysis and evaluation of antioxidant and free radical scavenging activity of Withania somnifera root. Asian J Pharm Clin Res. 2012;5(4):193-199.

[13] CLSI. Methods for Dilution Antimicrobial Susceptibility Tests for Bacteria That Grow Aerobically; Approved Standard - Ninth Edition. CLSI document M07-A9. Clinical and Laboratory Standards Institute, 950 West Valley Road, Suite 2500, Wayne, Pennsylvania 19087, USA, 2012.

[14] Compean KL, Ynalvez RA. Antimicrobial activity of plant secondary metabolites: A review. Res J Med Plants. 2014;8(5):204-213.

[15] Dadook M, Mehrabian S, Irian S. Antimicrobial effect of Cyperus rotundus on multiple drug resistant Pseudomonas aeruginosa strains. J Med Bacteriol. 2016;5(1):15-20.

[16] Essaidi I, Koubaier HBH, Snoussi A, Casabianca H, Chaabouni MM, Bouzouita N. Chemical composition of Cyperus rotundus L. tubers essential oil from the south of Tunisia, antioxidant potentiality and antibacterial activity against foodborne pathogens. J Essent Oil Bear Pl. 2014;17(3):522-532.

[17] Felhi S, Daoud A, Hajlaoui H, Mnafgui K, Gharsallah N, Kadri A. Solvent extraction effects on phytochemical constituents profiles, antioxidant and antimicrobial activities and functional group analysis of Ecballium elaterium seeds and peels fruits. Food Sci Technol. 2017;37(3):483-492.

[18] Figueiredo EAP, Ramos H, Maciel MAV, Vilar MDCM, Loureiro NG, Pereira RG. Pseudomonas aeruginosa: frequency of resistance to multiple drugs and cross-resistance between antimicrobials in Recife/PE. Rev Bras Terapia Intensiva. 2007;19(4):421-427.

[19] Firmo WCA, Menezes VDJM, Passos CEC, Dias CN, Alves LPL, Dias ICL, et al. Contexto histórico, uso popular e concepção científica sobre plantas medicinais. Cad Pesq. 2011;18:90-95.

[20] Forero-Doria O, Astudillo L, Castro RI, Lozano R, Díaz O, Guzman-Jofre L, et al. Antioxidant activity of bioactive extracts obtained from rhizomes of Cyperus digitatus Roxb. Bol Latinoam Caribe Plantas Med Aromát. 2014;13(4):344-350.

[21] Gamal MA, Hani KMK, Sabrin IRM. A review: Compounds isolated from Cyperus species (Part II): Terpenoidal. Int J Pharmacogn Phytochem Res. 2015;7(1):83-99.

[22] Gomes FMS, Xavier JC, Santos JFS, Matos YMLS, Tintino SR, Freitas TS, et al. Evaluation of antibacterial and modifying action of catechin antibiotics in resistant strains. Microb Pathog. 2018;115:175-178.

[23] Gopikrishnan V, Radhakrishnan M, Pazhanimurugan R, Shanmugasundaram T, Balagurunathan R. Antimicrobial, antitubercular and antiproliferative activities of quercetin isolated from the marine Streptomyces fradiae Bangladesh J Pharmacol. 2017;12(3):333-334.

[24] Hernando-Amado S, Coque TM, Baquero F, Martínez JL. Defining and combating antibiotic resistance from One Health and Global Health perspectives. Nat microbial. 2019;4(9):1432-1442.

[25] Ibrahim SRM, Mohamed GA, Khayat MTA, Zayed MF, El-Kholy AAES. Anti-inflammatory terpenoids from Cyperus rotundus rhizomes. Pak J Pharm Sci. 2018;31(4):1449-1456.

[26] Ito T, Endo H, Shinohara H, Oyama M, Akao Y, Iinuma M. Occurrence of stilbene oligomers in Cyperus rhizomes. Fitoterapia. 2012;83(8):1420-1429.

[27] Jaradat NA, Al-Masri M, Zaid NA, Hussein F, Al-Rimawi F, Mokh AA, et al. Phytochemical, antimicrobial and antioxidant preliminary screening of a traditional Palestinian medicinal plant, Ononis pubescens L. Eur J Integr Med. 2017;14:46-51.

[28] Jiménez CIE, Martínez EYC, Fonseca JG. Flavonoides y sus acciones antioxidantes. Rev Fac Med UNAM. 2009;52(2)73-5.

[29] Jing S, Li Q, Zheng L, Yue L, Fan S, Tao G. Dynamic high pressure microfluidization-assisted extraction and bioactivities of Cyperus esculentus (C. esculentus L.) leaves flavonoids. Food chem. 2016;192:319-327.

[30] Jung SH, Kim SJ, Jun BG, Lee KT, Hong SP, Oh MS, et al. α-Cyperone, isolated from the rhizomes of Cyperus rotundus, inhibits LPS-induced COX-2 expression and PGE2 production through the negative regulation of NFκB signalling in RAW 264.7 cells. J Ethnopharmacol. 2013;147(1):208-214.

[31] Kilani-Jaziri S, Bhouri W, Skandrani I, Limem I, Chekir-Ghedira L, Ghedira K. Phytochemical, antimicrobial, antioxidant and antigenotoxic potentials of Cyperus rotundus extracts. S Afr J Bot. 2011;77(3):767-776.

[32] Kishore G, Alluraiah G. Phytochemical screening and antimicrobial assessment of Cyperus iria (L) weeds roots. Bull Pharm Med Sci. 2013;1(2):151-156.

[33] Kobayashi CCBA, Sadoyama G, Vieira JDG. Determinação da resistência antimicrobiana associada em isolados clínicos de Staphylococcus aureus e Pseudomonas aeruginosa em um hospital público de Goiânia, Estado de Goiás. Rev Soc Bras Med Trop. 2009;42(4):404-410.

[34] Larridon I, Bauters K, Huygh W, Reynders M, Goetghebeur P. Taxonomic changes in C4 Cyperus (Cypereae, Cyperoideae, Cyperaceae): combining the sedge genera Ascolepis, Kyllinga and Pycreus into Cyperus sl. Phytotaxa. 2014;166(1):33-48.

[35] Lee KS, Park SN. Cytoprotective effects and mechanisms of quercetin, quercitrin and avicularin isolated from Lespedeza cuneata G. Don against ROS-induced cellular damage. J Ind Eng Chem. 2019;71:160-166.

[36] Li X, Jiang Q, Wang T, Liu J, Chen D. Comparison of the antioxidant effects of quercitrin and isoquercitrin: Understanding the role of the 6″-OH group. Molecules. 2016;21(9):1246.

[37] Lôbo KMS, Athayde ACR, Silva AMA, Rodrigues FFG, Lôbo IS, Bezerra DAC, et al. Avaliação da atividade antibacteriana e prospecção fitoquímica de Solanum paniculatum Lam. e Operculina hamiltonii (G. Don) DF Austin & Staples, do semi-árido paraibano. Rev Bras Plantas Med. 2010;12(2):227-235.

[38] Lubian CT, Teixeira JM, Lund RG, Nascente PS, Del Pino FAB. Atividade antifúngica do extrato aquoso de Arctium minus (Hill) Bernh.(Asteraceae) sobre espécies orais de Candida Rev Bras Plantas Med . 2010;12(2):157-162.

[39] Mensor LL, Menezes FS, Leitão GG, Reis AS, Santos TC, Coube CS, et al. Screnning of Brazilian plant extracts for antioxidant activity by the use of DPPH free radical method. Phytother Res . 2001;15(2):127-130.

[40] Metuge JA, Nyongbela KD, Mbah JA, Samje M, Fotso G, Babiaka SB, et al. Anti-Onchocerca activity and phytochemical analysis of an essential oil from Cyperus articulatus L. BMC Complement Altern Med. 2014;14(1)223.

[41] Nassar MI, Yassine YM, Elshamy AI, El-Beih AA, El-Shazly M, Singab ANB. Essential oil and antimicrobial activity of aerial parts of Cyperus leavigatus L.(Family: Cyperaceae). J Essent Oil Bear Plants. 2015;18(2):416-422.

[42] Oladosu IA, Usman LA, Olawore NO, Atata RF. Antibacterial activity of rhizomes essential oils of two types of Cyperus articulatus growing in Nigeria. Adv Biol Res. 2011;5(3):179-183.

[43] Oliveira CRV, Melo DB. Levantamento Fitoquímico da espécie Cyperus rotundus Rev Diálogos Cienc. 2018;3(40):1-10.

[44] Peerzada AM, Ali HH, Naeem M, Latif M, Bukhari AH, Tanveer A. Cyperus rotundus L.: traditional uses, phytochemistry, and pharmacological activities. J Ethnopharmacol. 2015;174:540-560.

[45] Pereira RJ, Cardoso MG. Metabólitos secundários vegetais e benefícios antioxidantes. J Biotec Biodivers. 2012;3(4):146-152.

[46] Quayyum HA, Mallikd AU, Leach M, Gottardo C. Growth inhibitory effects of nutgrass (Cyperus rotundus) on rice (Oryza sativa) seedlings. J Chem Ecol. 2000;26(9):2221-31.

[47] Reid CS, Carter R, Urbatsch LE. Phylogenetic insights into New World Cyperus (Cyperaceae) using nuclear ITS sequences. Brittonia. 2014;66(3)292-305.

[48] Sampaio FC, Pereira MSV, Dias CS, Costa VCO, Conde NCO, Buzalaf MAR. In vitro antimicrobial activity of Caesalpinia ferrea Martius fruits against oral pathogens. J Ethnopharmacol . 2009;124(2):289-294.

[49] Santana-Gálvez J, Cisneros-Zevallos L, Jacobo-Velázquez DA. Chlorogenic acid: Recent advances on its dual role as a food additive and a nutraceutical against metabolic syndrome. Molecules . 2017;22(3):358.

[50] Sartori GV, Costa CN, Ribeiro AB. Conteúdo fenólico e atividade antioxidante de polpas de frutas congeladas. Rev Bras Pesq Alimentos. 2014;5(3):23-29.

[51] Senger AEV, Schwanke CHA, Gottlieb MGV. Chá verde (Camellia sinensis) e suas propriedades funcionais nas doenças crônicas não transmissíveis. Sci Med. 2010;20(4):292-300.

[52] Sharma A, Verma R, Ramteke P. Cyperus rotundus: a potential novel source of therapeutic compound against urinary tract pathogens. J Herb Med. 2014;4(2):74-82.

[53] Simões RC, Almeida SSMS. Estudo fitoquímico de Bauhinia forficata (Fabaceae). Biota Amazônia. 2015;5(1):27-31.

[54] Silva ACO, Santana EF, Saraiva AM, Coutinho FN, Castro RHA, Pisciottano MNC, et al. Which approach is more effective in the selection of plants with antimicrobial activity? Evid Based Complement Alternat Med. 2013:1-9.

[55] Silva ICM, Santos WL, Leal ICR, Zoghbi MGB, Feirhmann AC, Cabral VF, et al. Extraction of essential oil from Cyperus articulatus L. var. articulatus (priprioca) with pressurized CO2. J Supercrit Fluids. 2014;88:134-141.

[56] Singh AP, Sharma SK. A new pentacyclic triterpenoid with antimicrobial activity from the tubers of Cyperus rotundus Linn. Hygeia J D Med. 2015;7(1):1-9.

[57] Sivapalan SR. Medicinal uses and pharmacological activities of Cyperus rotundus Linn-A Review. Int J Sci Res. 2013;3(5):1-8.

[58] Soumaya K.J., Zield G, Nouha N, Mounira K, Kamel G, Genviève FDM, et al. Evaluation of in vitro antioxidant and apoptotic activities of Cyperus rotundus Asian Pac J Trop Med. 2014;7(2)105-112.

[59] Storck CR, Nunes GL, Oliveira BB, Basso C. Folhas, talos, cascas e sementes de vegetais: composição nutricional, aproveitamento na alimentação e análise sensorial de preparações. Cienc Rural. 2013;43(3):537-543.

[60] Su M, Liu F, Luo Z, Wu H, Zhang X, Wang D, et al. The antibacterial activity and mechanism of chlorogenic acid against foodborne pathogen Pseudomonas aeruginosa Foodborne Pathog Dis. 2019;16(12):823-830.

[61] Veber J, Petrini LA, Andrade LB, Siviero J. Determinação dos compostos fenólicos e da capacidade antioxidante de extratos aquosos e etanólicos de Jambolão (Syzygium cumini L.). Rev Bras Plantas Med . 2015;17(2):267-273.

[62] Vechia CAD, Morais B, Schonell AP, Diel KAP, Faust C, Menin C, et al. Isolamento químico e validação analítica por cromatografia líquida de alta eficiência de quercitrina em Solidago chilensis Meyen (Asteraceae). Rev Bras Plantas Med . 2016;18(1):288-296.

[63] Vega-Morales T, Mateos-Díaz C, Pérez-Machín R, Wiebe J, Gericke NP, Alarcón C, et al. Chemical composition of industrially and laboratory processed Cyperus esculentus rhizomes. Food Chem. 2019;297:124896.

[64] Xu HB, Ma YB, Huang XY, Geng CA, Wang H, Zhao Y, et al. Bioactivity-guided isolation of anti-hepatitis B virus active sesquiterpenoids from the traditional Chinese medicine: rhizomes of Cyperus rotundus J Ethnopharmacol . 2015;171:131-140.

[65] Waterman PG, Mole S. Analysis of phenolic plant metabolites. Blackwell Scientific Publications. 1994;38(4):1064.

[66] Zhang TZ, Xu LJ, Xiao HP, Zhou X, Mo SM, Cai SM, et al. A new iridoid glycoside from the rhizomes of Cyperus rotundus B Korean Chem Soc. 2014;35(7):2207-2209.

[67] Zhang LL, Zhang LF, Hu QP, Hao DL, Xu JG. Chemical composition, antibacterial activity of Cyperus rotundus rhizomes essential oil against Staphylococcus aureus via membrane disruption and apoptosis pathway. Food control. 2017;80:290-296.

[68] Zhou B, Zeng J, Yan X, Jiang P, Liu G. Phytoactivity and antifungal activity of total alkaloids from stem of Cyperus iria J Trop Subtrop Bot. 2010;18(3):304-309.

[69] Zhou Z, Yin W. Two novel phenolic compounds from the rhizomes of Cyperus rotundus L. Molecules . 2012;17(11):12636-12641.

[70] Zhou Z, Zhang H. Phenolic and iridoid glycosides from the rhizomes of Cyperus rotundus L. Med Chem Res. 2013;22(10):4830-4835.

Retention time (min)	Compounds	λ1 (nm)	λ2 (nm)	λ3 (nm)
23,39	Catechin	233	279	-
27,25	Chlorogenic acid	-	246	325
45,03	Quercitrin	-	256	349
48,18	Quercetin		255	369

Hydroalcoholic extracts - AP	IC₅₀ - µg/mL	AA (% ± SD)¹
C. articulatus	395.57	52.32 ± 0.03
C. iria	321.33	48.74 ± 0.06
Hydroalcoholic extracts - UP	IC ₅₀ - µg/mL	AA (% ± SD) ¹
C. articulatus	1,114.01	24.51 ± 0.18
C. iria	436.82	42.95 ± 0.10
Reference Standard	IC ₅₀ - µg/mL	AA (% ± SD) ¹
Trolox®	1.8	92.45 ± 0.10

Brasil

Brasil

Phytochemical profile, evaluation of antimicrobial and antioxidant activity in vitro of the hydroalcoholic extract of two species of the genus Cyperus (Cyperaceae)

Abstract

INTRODUCTION

MATERIAL AND METHODS

Botanical material

Obtaining and concentrating extracts

Partitioning of bioactive extracts

Total phenols

High Performance Liquid Chromatography (HPLC)

In vitro antioxidant activity

In vitro antimicrobial activity

Minimum Inhibitory Concentration (MIC)

Minimum Bactericidal and Fungicidal Concentration (MBC and MFC)

Statistical analyzes

RESULTS AND DISCUSSION

Total phenols

High Performance Liquid Chromatography (HPLC)

In vitro antioxidant activity

In vitro antimicrobial activity

CONCLUSION

ACKNOWLEDGEMENTS

REFERENCES

FUNDING

Publication Dates

History

Strains	EAFCAAP (µg/mL)	CFCAUP (µg/mL)	EAFCIAP (µg/mL)	CFCIUP (µg/mL)
	MIC	MIC	MIC	MIC
Candida albicans	-	62.5	-	31.2
Staphylococcus aureus	125	125	-	31.2
Pseudomonas aeruginosa	-	250	-	250
	MFC	MFC	MFC	MFC
Candida albicans	-	125	-	31.2
	MBC	MBC	MBC	MBC
Staphylococcus aureus	-	500	-	250
Pseudomonas aeruginosa	-	250	-	250