Phytochemical study and antioxidant activity of <i>Dalbergia ecastaphyllum</i>

Lucas, Cátia Ionara Santos; Ferreira, Adailton Freitas; Costa, Maria Angélica Pereira de Carvalho; Silva, Fabiane de Lima; Estevinho, Leticia Miranda; Carvalho, Carlos Alfredo Lopes de

doi:10.1590/2175-7860202071049

Abstract

The chemical profile of Dalbergia ecastaphyllum has been indicated as the botanical origin of Brazilian red propolis, an apicultural product with proven therapeutic properties. However, few studies have investigated this plant species. This study evaluated and compared microbiological quality, chemical composition, and antioxidant activity of stem and leaf samples of D. ecastaphyllum. The samples were collected in February 2015, in the southern region of the state of Bahia, Brazil. We performed the microbiological analyses, determined the contents of fatty acid, total phenol and flavonoid, and identified the chemical profile and antioxidant activit. Escherichia coli, Salmonella spp. and sulfite reducing clostridial spores were not detected in the samples. Acids of the family ω3 were recorded in the stems and ω6 in the leaves. The leaves presented better nutritional quality of the fraction, better antioxidant capacity in the tests by the DPPH method and β-carotene bleaching. There were 49 chemical compounds, of which 38 belonged to the class of flavonoids. The results indicate that stems and leaves of D. ecastaphyllum have biological properties. Leaves particularly are better for functional food formulation and as natural antioxidant.

Key words:
DPPH; fatty acids; flavonoids; LC-MS; omega-6

Resumo

O perfil químico de Dalbergia ecastaphyllum tem sido indicado como a provável origem botânica da própolis vermelha brasileira, um produto apícola com inúmeras propriedades terapêuticas comprovadas. No entanto, existem poucas pesquisas dedicadas a esta espécie de planta. O objetivo deste estudo foi avaliar e comparar a qualidade microbiológica, composição química e atividade antioxidante de amostras de caule e folhas de D. ecastaphyllum. As amostras foram coletadas em fevereiro de 2015, na região sul do estado da Bahia, Brasil. Análises microbiológicas, determinação de ácidos graxos, conteúdo total de fenóis e flavonoides, identificação do perfil químico e atividade antioxidante foram realizados. Escherichia coli, Salmonella spp. e esporos de clostridios redutores de sulfito estavam ausentes em todas as amostras. Ácidos da família ω3 foram registrados nos caules e ω6 nas folhas. A folha apresentou melhor qualidade nutricional da fração, melhor capacidade antioxidante nos testes pelo método DPPH e branqueamento β-caroteno. Foram encontrados 49 compostos químicos, dos quais 38 pertenciam à classe dos flavonoides. Os resultados indicam que o caule e a folha de D. ecastaphyllum possuem propriedades biológicas, particularmente as folhas são melhores para uso na formulação de alimentos funcionais e como antioxidante natural.

Palavras-chave:
DPPH; ácidos graxos; flavonoides; LC-MS; ômega-6

Introduction

Dalbergia ecastaphyllum (L.) Taub. belongs to the Fabaceae family and is widely distributed along the coast of the Americas (from southern Florida to southern Brazil) as well as on the eastern coast of the African continent. The occurrence of this species is usually associated with areas of riverbeds, mangroves and restinga vegetation (Carvalho 1997Carvalho AM (1997) A synopsis of the genus Dalbergia (Fabaceae: Dalbergieae) in Brazil. Brittonia 49: 87-100. ). Dalbergia ecastaphyllum has a growth of liana shrub, incandescent or semi-prostrate and presents a tangle of branches and a stem that contributes to better fixation (Lima 2015Lima HC (2015). Dalbergia. In: Lista de Espécies da Flora do Brasil. Instituto de Pesquisas Jardim Botânico do Rio de Janeiro. Disponivel em <http://floradobrasil.jbrj.gov.br/jabot/floradobrasil/FB22908>. Acesso em mai 2018.
http://floradobrasil.jbrj.gov.br/jabot/f... ).

This species is widely used in the recovery of areas degraded by floods (Bohrer et al. 2009Bohrer CBA, Dantas HGR, Gronemberger FM, Vincens RS & Andrade SF (2009) Mapeamento de vegetação e do uso do solo no centro de diversidade vegetal de Cabo Frio, Rio de Janeiro, Brasil. Rodriguésia 60: 1-23.). It is also used in traditional medicine a diuretic, emetic remedy as well as in inhalations, control of uterine inflammation and anemia (Guedes et al. 2014Guedes GMM, Albuquerque RS, Soares-Maciel RS, Freitas MA, Silva VA, Lima EO, Lima MA Cunha EVL & Coutinho HDM (2014) Isolation of phytosterols of Dalbergia ecastophyllum (L.) Taub. (Leguminosae) and modulation of antibiotic resistance by a possible membrane effect. Arabian Journal of Chemistry: 1-5.). In the phytochemical screening of extracts from various parts in plants of this genus, metabolites with broad biological performance were identified, such as antioxidant (Lianhe et al. 2012Lianhe Z, Xing H, Li W & Zhengxing C (2012) Physicochemical properties, chemical composition and antioxidant activity of Dalbergia odorifera T. Chen seed oil. Journal of the American Oil Chemists' Society 89: 883-890. ), anti-inflammatory (Ganga et al. 2012Ganga RB, Madhu KP & Vijaya RAD (2012) Investigation of antioxidant and anti-inflammatory activity of leaves of Dalbergia paniculata (Roxb). Asian Pacific Journal of Tropical Medicine 5: 455-458. ), antimicrobial (Mutai et al. 2013Mutai P, Heydenreich M, Thoithi G, Mugumbate G, Chibale K & Yenesew A (2013) 3-Hydroxyisoflavanones from the stem bark of Dalbergia melanoxylon: Isolation, antimycobacterial evaluation and molecular docking studies. Phytochemistry Letters 6: 671-675. ; Guedes et al. 2014Guedes GMM, Albuquerque RS, Soares-Maciel RS, Freitas MA, Silva VA, Lima EO, Lima MA Cunha EVL & Coutinho HDM (2014) Isolation of phytosterols of Dalbergia ecastophyllum (L.) Taub. (Leguminosae) and modulation of antibiotic resistance by a possible membrane effect. Arabian Journal of Chemistry: 1-5.), cytotoxicity (Saha et al. 2013Saha S, Anisuzzman M, Islam MK, Mondal H & Talukder C (2013) Antibacterial and cytotoxic potential of Dalbergia spinosa Roxb. leaves. International Journal of Pharmaceutical Sciences Review and Research 4: 512-515. ), photoprotective (Martins et al. 2016Martins FJ, Caneschi CA, Vieira JLF, Barbosa W & Raposo NRB (2016) Antioxidant activity and potential photoprotective from amazon native flora extracts. Journal of Photochemistry and Photobiology B: Biology 161: 34-39.), among others. Souza et al. (2015)Souza AHP, Corrêa RCG, Barros L, Calhelha RC, Santos-Buelga C, Peralta RM, Bracht A, Matsushita M & Ferreira ICFR (2015) Phytochemicals and biactive properties of Ile paraguariensis: na in-vitro comparatives study between the whole plant, leaves and stems. Food Research International 78: 286-294. argue that plant parts may present different chemical compositions and consequently different biological activities.

According to the chromatographic methods, isoflavonoids are the main constituent metabolites of D. ecastaphyllum, namely biochanin A, daidzein, dalbergin, formononetin, isoliquiritigenin, medicarpin, 3-Hydroxy-8,9-dimethoxypterocarpan and liquiritigenin (Donnelly et al. 1973Donnelly DMX, Keenan PJ & Prendergast JP (1973) Isoflavonoids of Dalbergia ecastophyllum. Phytochemistry 12: 1157-1161. ; Matos et al. 1975Matos FJA, Gottlieb OR & Andrade CHS (1975) Flavonoids from Dalbergia ecastophyllum. Phytochemistry 14: 825-826.; Daugsch et al. 2008Daugsch A, Morais CS, Fort P & Park YK (2008) Brazilian red própolis - chemical composition and botanical origin. Evidence-based complementary and alternative medicine 5: 435-441. ; Piccinelli et al. 2011Piccinelli AL, Lotti C, Campone L, Cuesta-Rubio O, Fernandez MC & Rastrelli L (2011) Cuban and Brazilian red propolis: botanical origin and comparative analysis by high-performance liquid chromatography-photodiode array detection/electrospray ionization tandem mass spectrometry. Journal of Agricultural and Food Chemistry 59: 6484-6491.). Some of these compounds have also been identified in samples of red propolis whose chemical profile D. ecastaphyllum is indicated as the botanical origin of this bee product (Mendonça-Melo et al. 2017Mendonça-Melo L, Mota E, Lopez B, Sawaya A, Freitas L, Jain S, Batista M & Araújo E (2017) Chemical and genetic similarity between Dalbergia ecastaphyllum and red propolis from the Northeastern Brazil. Journal of Apicultural Research 56: 1-8. ).

Many studies have identified and elucidated numerous biological actions of red propolis (Rufatto et al. 2017Rufatto LC, Santos DA, Marinho F, Henriques JAP, Ely MR & Moura S (2017) Red propolis: chemical composition and pharmacological activity. Asian Pacific Journal of Tropical Biomedicine 7: 591-598.); however, few studies have investigated its primary source. Although some studies have investigated D. ecastaphyllum, its bioactive compounds, microbiological quality and antioxidant activity are not well known. This study evaluated and compared microbiological quality, chemical composition and antioxidant activity of stem and leaf samples of D. ecastaphyllum.

Materials and Methods

Sampling

Samples of stems (n = 5) and leaves (n = 5) of D. ecastaphyllum (L.) Taub. were collected in February 2015 in different sites in the municipalities of Canavieiras (15º40'30"S, 38º56'50"W) and Ilhéus (14º47'20"S, 39º02'58"W) in the state of Bahia, Brazil, located in the region with phytophysiognomy of the Atlantic Forest and mangrove vegetation. The sampling sites were linked to the environment of red propolis apiaries. For each site, a plant was selected randomly to collect samples of stems with 10 cm in length X 3 cm in diameter and adult leaves. These samples were dried in air circulating greenhouses (40 ºC) for 72 h and then ground in knife mill.

The specimens were herborized and sent to the Herbarium of the Federal University of Recôncavo da Bahia (HURB), where they were identified and deposited in vouchers 11,507 and 11,509, respectively, collected in the municipality of Canavieiras and Ilhéus.

Microbiological analyses

Ten grams of the material in natura were weighed 90 ml of sterile peptone saline solution and homogenized for 2 min in Stomacher Lab-Blender (Seward type 400, London, United Kingdom). For the quantification of the colony forming units of aerobic mesophilic microorganisms, using the methodology recommended by Silva et al. (2010)Silva N, Junqueira VCA, Silveira NFA, Taniwaki MH, Santos RFS & Gomes RAR (2010) Manual de métodos de análises microbiológicas de alimentos e água. 4a ed. Varela, São Paulo. 632p. and for molds and yeasts in ISO 21527-2 (2008)ISO 21527-2 (2008) Microbiology of food and animal feeding stuffs - horizontal method for the enumeration of yeasts and moulds - part 2: colony count technique in products with water activity less than or equal to 0.95. International Standards Organization, Winterthur. 17p.. The quantification of Coagulase-positive Staphylococcus and Clostridium Sulphite Reduction Spores was performed according to Bennett and Lancette (2001)Bennett RW & Lancette GA (2001) Staphylococcus aureus. Ch.12, rev. Jan. 2001. In: FDA bacteriological analytical manual, 8th ed. rev. AOAC International, Gaitherburg. Available at <http://cfsan.fda.gov/~ebam/bam-12.html>. Access in Jan 2019.
http://cfsan.fda.gov/~ebam/bam-12.html... and ISO 15213 (2003)ISO 15213 (2003) Microbiology of food and animal feeding stuffs - Horizontal method for the enumeration of sulfite-reducing bacteria growing under anaerobic conditions. International Standards Organization, Winterthur. 12p.. The counts of coliforms and Escherichia coli were obtained by the SimPlate method (BioControl) and the detection of Salmonella spp. by the Immunodiffusion 1-2 Test (AOAC 2005AOAC (2005) Microbiological methods. In: Official methods of analysis. 16th ed. Association of Official Analytical Chemists, Arlington. 246p.).

Chemical composition

Hydro-alcoholic extract

In the extraction, 1 g of the dried and ground samples were used in 12.5 mL of 70% ethanol at constant shaking at room temperature for 14 d. Afterwards, the samples were placed in ultrasonic bath (1h) and centrifuged at 3,000 rpm/10 min, filtered and evaporated under low pressure. After solvent evaporation and stability of samples weight, the dried extract was placed in a freezer (-20 ºC). The extracts used in the analyses were solubilized in methanol at a concentration of 4 mg/mL (Park et al. 1998Park YK, Ikegari M, Abreu JAS & Alcici NMF (1998) Estudo da preparação dos extratos de própolis e suas aplicações. Ciência e Tecnologia de Alimentos 18: 313-318.).

Fatty acids

The profile of fatty acids in the samples was determined by gas-liquid chromatography with flame ionization detection (GC-FID at 260 ºC) according to Barros et al. (2013)Barros L, Pereira E, Calhelha RC, Dueñas M, Carvalho AM, Santos-Buelga C & Ferreira ICFR (2013) Bioactivity and chemical characterization in hydrophilic and lipophilic compounds of Chenopodium ambrosioides L. Journal of Functional Foods 5: 1732-1740.. A capillary column was used in DANI GC 1,000 (Izasa, Barcelona, Spain) instrument, equipped with a split/splitless injector, with a flame ionization detector (FID) and a Macherey-Nagel column (25 × 0.32 Mm ID × 0.25 µm df). The method involves the transesterification process, which consists of solubilization of samples in methanol, followed by the addition of sulfuric acid and toluene (at a ratio 2: 1: 1 (v / v / v)) for at least 12 h in bath at 50 ºC and 160 rpm. It was added 3 mL of deionized water and 3 mL of diethyl ether to this mixture for phase separation. After separation, the lipid phase was extracted, filtered on a column containing sodium sulphate and packed in an amber vessel.

The oven temperature ranged from 30 ºC to 220 ºC, totaling 35.16 min per analysis. The gas (hydrogen) was kept at a flow rate of 4.0 mL/min (0.61 bar), measured at 50 ºC. A volume of 1 µL of transesterified sample was injected into the GC. Fatty acids were identified by comparing the retention times relative to the peaks of standard FAME samples. The results were recorded and processed using CSW 1.7 software (DataApex 1.7, Prague, Czech Republic) and expressed as a relative percentage of each fatty acid calculated by internal normalization of the peak area of the chromatographic peak.

Nutritional quality index of lipid fraction

To assess the nutritional quality of lipids, we determined the Atherogenicity Index (IA), Thrombogenicity Index (IT) (Ulbricht & Southgate 1991Ulbricht TLV & Southgate DAT (1991) Coronary heart disease: seven dietary factors. The Lancet 19: 985-992.) and the relationship between hypocholesterolemic/hypercholesterolemic (H/H) (Santos-Silva et al. 2002Santos-Silva J, Bessa RJB & Santos-Silva F (2002) Effect of genotype, feeding system and slaughter weight on the quality of light lambs. II. Fatty acid composition of meat. Livestock Production Science 77: 187-194. ).

Total phenols and total flavonoids

The total phenol content and total flavonoids of the methanolic extract of stems and leaves were determined by the colorimetric method, Folin-Ciocalteu (Singleton et al. 1999Singleton VL, Orthofer R & Lamuela-Raventos RM (1999) Analysis of total phenols and other oxidation substrates and antioxidants by means of Folin-Ciocalteu reagent. Methods in Enzymology 299: 152-178.) and Aluminum Chloride (Alencar et al. 2007Alencar SM, Oldoni TLC, Castro ML, Cabral ISR, Costa-Neto CM, Cury JA, Rosalen PL & Ikegaki M (2007) Chemical composition and biological activity of a new type of Brazilian propolis: red própolis. Journal of Ethnopharmacology 113: 278-283.), respectively. The extracts (0.5 mL) were mixed with 2.5 mL of Folin-Ciocalteu reagent (1:10) and 2.0 mL of Na₂CO₃(4% sodium carbonate). After incubation for 2 h at room temperature, absorbance at 760 nm was determined. The results were expressed as milligram equivalents of Gallic acid per gram of extract (mg GAE / g) from the standard curve (y = 0.0093x + 0.0287; R² = 0.9999). To obtain the total flavonoid content, 2 mL of the extract was mixed with 2 mL of AlCl₃(2% aluminum chloride). Absorbance was measured at 420 nm after 1 h of incubation at room temperature and the result expressed as milligram equivalent of quercetin per gram of extract (mg QE / g) from the standard curve (y = 0.0353x + 0.0073; R² = 0.9995).

Identification of chemical compounds by LC / MS

The identification of the chemical compounds in stem and leaf samples of D. ecastaphyllum were performed using Liquid Chromatography coupled to the LTQ Orbitrap XL^TM mass spectrometer (Thermo Fischer Scientific, Bremen, Germany), controlled by LTQ Tune Plus 2.5.5, for the control and acquisition of the data the system Xcalibur 2.1.0. The mobile phase consisted of a system gradient: 0.1% formic acid in Milli-Q (A) water and HPLC-grade methanol (B). The separation was performed using the Gemini C18 reverse phase column (250 × 4.6 mm, 5 µm) of Phenomenex in negative mode, kept at 25 ºC, the chromatographic data acquired by three channels of 280 nm, 320 nm and 360 nm readings and fractions to the UV profile display (Falcão et al. 2013Falcão SI, Tomás A, Vale N, Gomes P, Freire C & Vilas-Boas M (2013) Phenolic quantification and botanical origin of Portuguese propolis. Industrial Crops and Products 49: 805-812. ).

Antioxidant activity

The antioxidant capacity was determined by the physical method, known as radical sequestering activity (DPPH), and the chemical method, based on the transfer of hydrogen atoms (β-carotene/linoleic acid system) (Alves et al. 2010Alves CQ, David JM, David JP, Bahia MV & Aguiar RM (2010) Métodos para determinação de atividade antioxidante in vitro em substratos orgânicos. Química Nova 33: 2202-2210.). Butylhydroxyanisole (BHA) and ascorbic acid, synthetic antioxidant and natural antioxidant respectively, were used as reference substances for both methods.

Free radical scavenging activity - DPPH (1,1-diphenyl-2-picrylhydrazyl)

The measurement of the DPPH radical sequestering activity of methanolic extracts at different concentrations were performed according to methodology established by Barros et al. (2013)Barros L, Pereira E, Calhelha RC, Dueñas M, Carvalho AM, Santos-Buelga C & Ferreira ICFR (2013) Bioactivity and chemical characterization in hydrophilic and lipophilic compounds of Chenopodium ambrosioides L. Journal of Functional Foods 5: 1732-1740.. In this physical method, the reaction mixture consisted of 0.3 mL of the sample at different concentrations (0.004 to 0.4 mg/mL) and 2.7 mL of the 0.5 mM solution of DPPH in methanol. After incubation for 1 h at room temperature, the absorbance reading was performed at 517 nm. The antioxidant activity was expressed by EC50, that is, the concentration that induces half the maximum effect.

β-carotene bleaching assay

The coupled oxidation of β-carotene/linoleic acid was performed according to Barros et al. (2013)Barros L, Pereira E, Calhelha RC, Dueñas M, Carvalho AM, Santos-Buelga C & Ferreira ICFR (2013) Bioactivity and chemical characterization in hydrophilic and lipophilic compounds of Chenopodium ambrosioides L. Journal of Functional Foods 5: 1732-1740.. In this chemical method, 5 mg of β-carotene were weighed and diluted in 25 mL of chloroform. A 4-mL aliquot was added, and 80 µL of linoleic acid and 800 µL of Tween 20 were added. The reaction mixture was subjected to complete chloroform evaporation using a rotary evaporator, the residue obtained was redissolved in 200 mL of water Deionized, previously saturated with oxygen for 30 min. Aliquots of 4.5 mL of the β-carotene/linoleic acid emulsion were mixed with 0.2 mL of 0.1 mg/mL methanolic extracts. Emulsion oxidation was monitored spectrometrically (UV-visible - Unicam Hekios Alpha), absorbance was measured at 470 nm at the initial time (t = 0) and after 2 h of incubation at 50°C. The antioxidant activity (AA) was expressed by inhibition percentage in relation to the control (emulsion + methanol) after a 2-h incubation period.

Statistical analyses

The experimental results were presented as means ± standard deviation. For the inferential analysis, normality was verified by the Shapiro-Wilks test and the variance homogeneity by the Levene's and Bartlett's tests. The unpaired Student t-test was used to compare the differences between the means of treatment groups (stem and leaf), when values were within the normal distribution (fatty acids, phenol content, DPPH and β-carotene/Linoleic acid) or the non-parametric Mann-Whitney test, when values did not fit into the normal distribution (flavonoid content and microorganism counts). The multivariate analysis of canonical correlation was performed to establish correlation between two groups of variables, that is, the group formed by the content of phenols and flavonoids with the second group formed by the different antioxidant methods in stems and leaves (β-carotene/linoleic acid and DPPH). The first group represents the dependent variables (Y), while the second group represents the independent variables (X). The Hotelling multivariate test (approximation of the F distribution) was used to verify the significance of pairs of canonical variables (Johnson & Wichern 1992Johnson RA & Wichern DW (1992) Applied multivariate statistical analysis. 3rd ed. Prentice-Hall, New Jersey. 642p.). The variance percentage explained by the canonical variable was determined by the square of the canonical correlation. All analyses were performed in the statistical program R (version 3.3.0) at 5% (p < 0.05) significance level.

Results and Discussion

Microbiological analyses

As seen in Figure 1, the total colony-forming unit count for the mesophilic aerobic microorganisms (ranging to 9x10³ to 2x10⁵ cfu.g^-1), molds and yeasts (ranging to 2×10² to 3×10⁴ cfu.g^-1) (Mann-Whitney U test, p < 0.00001), were significantly higher in the stems than in the leaves of D. ecastaphyllum. Plants normally have a microbial load from the soil, water and air; however, as the stem is located in a more shaded and moist area of the plant, it has more favorable conditions for the proliferation of microorganisms (Huang et al. 2012Huang L, Gao X, Liu M, Du G, Guo J & Ntakirutimana T (2012) Correlation among soil microorganisms, soil enzyme activities, and removal rates of pollutants in three constructed wetlands purifying micro-polluted river water. Ecological Engineering 46: 98-106. ).

Figure 1 – a-c
Contamination level in leaves and stems samples of Dalbergia ecastaphyllum – a. of aerobic mesophilic microorganisms; b. of molds and yeasts; c. of total coliforms. Statistical significance was determined using the Mann- Whitney U test (***: p < 0.001; ****: p < 0.0001).

The determination of fungi in vegetables and processed foods is of great importance due to risks to human and animal health, since some fungi produce toxic secondary metabolites. On the other hand, fungi such as endophytes, associated to medicinal plant tissues, may contain bioactive compounds economically useful to human health (Toghueo et al. 2017Toghueo RMK, Zabalgogeazcoa I, Vázquez de Aldana BR & Boyom FF (2017) Enzymatic activity of endophytic fungi from the medicinal plants Terminalia catappa, Terminalia mantaly and Cananga odorata. South African Journal of Botany 109: 146-153. ).

The count of aerobic mesophilic microorganisms, as well as of molds and yeasts, is commonly used as a general indicator of product quality. Total coliforms are also indicators of contamination during production, harvesting, and processing stages, and the best indicators are the presence of pathogenic microorganisms of enteric origin, such as Escherichia coli (Brasil 2010Brasil - Ministério da Saúde - Agência Nacional de Vigilância Sanitária (2010) Farmacopeia brasileira. Vol 2. Anvisa, Brasília. 546p.). No Escherichia coli, Staphylococcus spp., clostridium sulphite reducing spores and Salmonella spp. were found in the samples. The absence of these microorganisms indicates that plant tissues of D. ecastaphyllum are safe, from a microbiological viewpoint. This is important because these microorganisms are potentially pathogenic and of interest to public health (De-Melo et al. 2015De-Melo AAM, Estevinho MLMF & Almeida-Muradian LB (2015) A diagnosis of the microbiological quality of dehydrated bee-pollen produced in Brazil. Letters in Applied Microbiology 61: 477-483. ).

Fatty acids

In the lipid composition of stems and leaves of D. ecastaphyllum, 21 types of methyl ester acids were identified, with higher percentages for saturated acids (SFA), followed by polyunsaturated fatty acids (PUFA) and monounsaturated fatty acids (MUFA). The amount of SFA in stems (58.81 ± 7.65%) was higher (p < 0.05) than in leaves, PUFA were higher (p < 0.05) in leaves (46.06 ± 4.43%) than in stems, and for MUFA, there was no statistical difference between the samples. Among the SFA, C16: 0 (palmitic acid) presented higher levels and did not differ statistically between the samples. For PUFA, C18: 2n6c (linoleic acid) was more present (p < 0.05) in the stem (24.50 ± 5.16%), while in the leaves the most abundant was C18: 3n3 (linolenic acid (41.54 ± 4.06%). These PUFA contributed the highest percentage of omega-6 (ω6) in the stems and of omega-3 (ω3) in the leaves (Tab. 1).

Thumbnail

Table 1
Chemical composition of fatty acids in stem and leaf samples of Dalbergia ecastaphyllum. The results of the fatty acids were expressed in relative percentage. Averages followed by an asterisk (*) differ statistically by the Student t-test (p < 0.05); ^a = Standard deviation; ^b = Not found; ^c = Total saturated fatty acids; ^d = Total monounsaturated fatty acids; ^e = Total polyunsaturated fatty acids; ^f = Total omega-6 fatty acids; ^g = Total omega-3 fatty acids; ^h = Proportion of polyunsaturated and saturated fatty acids; ⁱ = Proportion of omega-6 and omega-3 fatty acids; ^j = Atherogenicity index; ^k = Thrombogenicity index; ^l = Relation of hypocholesterolemic / hypercholesterolemic fatty acid.

In a comparative study of leaves, stems and the entire plant of Ilex paraguariensis, C18: 3n3 was pronounced in leaves (60.3 ± 0.3%) and C16: 0 was higher in stems (25.2 ± 1.8%) (Souza et al. 2015Souza AHP, Corrêa RCG, Barros L, Calhelha RC, Santos-Buelga C, Peralta RM, Bracht A, Matsushita M & Ferreira ICFR (2015) Phytochemicals and biactive properties of Ile paraguariensis: na in-vitro comparatives study between the whole plant, leaves and stems. Food Research International 78: 286-294.), with difference in the chemical composition in the different plant parts. In this study, we also observed difference for C18: 3n3 between the stems and leaves, with the highest concentration observed in leaves. However, no difference was found in the C16: 0 content between the stems and leaves.

In D. odorifera T. Chen seed oils, C18: 2n6c was predominant when compared to C18: 3n3 (Lianhe et al. 2012Lianhe Z, Xing H, Li W & Zhengxing C (2012) Physicochemical properties, chemical composition and antioxidant activity of Dalbergia odorifera T. Chen seed oil. Journal of the American Oil Chemists' Society 89: 883-890. ). This result was similar to our study for stem samples of D. ecastaphyllum, while an inverse relationship for acids was observed in the leaves. These differences may be related to the characteristics of each species, as well as the soil and climatic conditions where the samples were collected.

Fatty acids are energetic sources and play important metabolic functions in the constitution of the cell membrane phospholipid bilayer, in regulating intracellular signaling pathways, transcription factors, and gene expression, as well as in the production of bioactive lipid mediators (Calder 2015Calder PC (2015) Functional roles of fatty acids and their effects on human health. Journal of Parenteral and Enteral Nutrition 39: 1-15. ). Among fatty acids, the palmitic acid is the most abundant in the human body and has the function of guaranteeing the physical properties of the cell membrane (Carta et al. 2017Carta G, Murru E, Banni S & Manca C (2017) Palmitic acid: physiological role, metabolism and nutritional implications. Frontiers in Physiology 8: 1-14. ). It has also been reported as a precursor of the sapienic acid (C16: 1n10), which is present in sebaceous glands in the skin (Ge et al. 2003Ge L, Gordon JS, Hsuan C, Stenn K & Prouty SM (2003) Identification of the delta-6 desaturase of human sebaceous glands: expression and enzyme activity. Journal of Investigative Dermatology 120: 707-714. ). Factors, such as excessive dietary carbohydrate and alcoholic beverages associated to a sedentary lifestyle, can trigger a dietary imbalance of C16: 0 with polyunsaturated acids, generating negative effects on human health (Carta et al. 2017Carta G, Murru E, Banni S & Manca C (2017) Palmitic acid: physiological role, metabolism and nutritional implications. Frontiers in Physiology 8: 1-14. ).

The stems and leaves of D. ecastaphyllum evaluated in this study presented values that could improve the diet characteristics, although the leaves were nutritionally better (p < 0.05) with higher PUFA: SAT ratio (0.92 ± 0.15) and lower ratio n -6: n -3 (0.10 ± 0.03). The stems and leaves of D. ecastaphyllum evaluated in this study presented values that could improve the characteristics of the diet, although the leaves were nutritionally better (p < 0.05) with higher PUFA: SAT ratio (0.92 ± 0.15) and lower ratio n -6: n -3 (0.10 ± 0.03). According to the Department of Health and Social Security of London (United Kingdom) (1994)Department of Health and Social Security (1994) Nutritional aspects of cardiovascular disease. Report on health and social subjects no 46. HMSO Her Majesty's Stationer Office, London. 178p. and Santos-Silva et al. (2002)Santos-Silva J, Bessa RJB & Santos-Silva F (2002) Effect of genotype, feeding system and slaughter weight on the quality of light lambs. II. Fatty acid composition of meat. Livestock Production Science 77: 187-194. , foods with values lower than 0.45 PUFA: SAT favor the increase cholesterol levels in the blood and values higher than 4.0 n-6: n-3 ratio contribute to cardiovascular diseases. The presence of the omega-6 and omega-3 in polyunsaturated acids, respectively in the stem and leaf, contributed to the nutritional quality of the samples, since diets rich in these acids have a preventive action on diseases, such as cardiovascular diseases (Zhuang et al. 2018Zhuang P, Wang W, Wang J, Zhang Y & Jiao J (2018) Polyunsaturated fatty acids intake, omega-6/omega-3 ratio and mortality: findings from two independent nationwide cohorts. Clinical Nutrition 38: 848-855.).

The AI (Atogenogenicity Index) and TI (Thrombogenicity Index) indexes in the leaves of D. ecastaphyllum were lower (p < 0.05) than in the stems and an inverse relationship was found for the HH (Hypocholesterolemic/Hypercholesterolemic) index (Tab. 1). These indices indicate that diets with low AI and TI values may decrease the risk of coronary heart disease associated in isolation or synergy, respectively, with atherosclerosis and thrombosis (Ulbricht & Southgate 1991Ulbricht TLV & Southgate DAT (1991) Coronary heart disease: seven dietary factors. The Lancet 19: 985-992.; Souza et al. 2015Souza AHP, Corrêa RCG, Barros L, Calhelha RC, Santos-Buelga C, Peralta RM, Bracht A, Matsushita M & Ferreira ICFR (2015) Phytochemicals and biactive properties of Ile paraguariensis: na in-vitro comparatives study between the whole plant, leaves and stems. Food Research International 78: 286-294.). HH is directly related to cholesterol metabolism and studies on leafy vegetables have shown that HH are effective in reducing the hypercholesterolemic state in experimental models (Cheurfa & Allem 2015Cheurfa M & Allem R (2015) Study of hypocholesterolemic activity of Algerian Pistacia lentiscus leaves extracts in vivo. Revista Brasileira de Farmacognosia 25: 142-144.). For these indices, no reference values have yet been established.

Total phenols and total flavonoids

The leaves had higher phenolic contents (698.52 ± 9.64%, Student t-test, p = 0.00001, Fig. 2a) and flavonoids (47.51 ± 2.21%, Mann-Whitney test, p = 0.00001; Fig. 2b) than the stems did. Chaitra et al. (2015)Chaitra S, Kumar NN, Shalini P & Sharu Raj KM (2015) In vitro antioxidant activity of methanolic extracts of Dalbergia paniculata Roxb. International Journal of Pharmacy and Pharmaceutical Sciences 5: 938-944., analyzing the levels of phenolic compounds by spectrophotometric method with standards similar to that of this study, found higher values of phenols in stems (9.32 mg GAE / g) than in leaves (8.54 mg GAE / g) of D. paniculata Rouxb. Similar result was reported for stem flavonoids (13.22 mg QE / g) of Grewia carpinifolia (Adebiyia et al. 2017Adebiyia OE, Olayemi FO, Ning-Hua T & Guang-Zhi Z (2017) In vitro antioxidant activity, total phenolic and flavonoid contents of ethanol extract of stem and leaf of Grewia carpinifolia. Beni-Suef University Journal of Basic and Applied Sciences 6: 10-14.). Liu et al. (2017)Liu S, Lin J, Hu C, Shen B, Chen T, Chang Y, Shih C & Yang D (2017) Phenolic compositions and antioxidant attributes of leaves and stems from three inbred varieties of Lycium chinense Miller harvested at various times. Food Chemistry 215: 284-291. observed that the environment temperature could be a relevant factor to quantify phenol and flavonoid contents in the different plant parts, not obtaining, exclusively, a preponderant value for stems or leaves of the species Lycium chinense Miller.

Figure 2
a. Total phenol content; b. total flavonoid content; c. antioxidant activity of the stem and leaf extracts of Dalbergia ecastaphyllum by DPPH; d. β-carotene/linoleic acid. Statistical significance was determined using the Student t-test for the total phenol variables (***: p < 0.0001) and β-carotene/linoleic acid (**: p = 0.01) and the Mann-Whitney U test for Variable total flavonoids (****: p < 0.0001) and DPPH (****: p < 0.0001). GAE = Gallic acid Equivalent; QE = Quercetin Equivalent; DPPH = 1,1-diphenyl-2-picrylhydrazyl; EC 50 = concentration that induces half the maximum effect.

Comparing the content of phenolic compounds in methanolic extracts of stems and leaves of D. ecastaphyllum with the ethanolic extract of red propolis from Sergipe state (300.36 ± 0.01 mg GAE / g and 57.6 ± 0.01 mg QE / g) and from Alagoas state (197.77 ± 0.01 mg GAE / g and 58.19 ± 0.01 mg QE / g) (Machado et al. 2016Machado BAS, Silva RPD, Barreto GA, Costa SS, Silva DF, Brandão HN, Rocha JLC, Dellagostin, OA, Henriques JAP, Umsza-Guez MA & Padilha FF (2016) Chemical composition and biological activity of extracts obtained by supercritical extraction and ethanolic extraction of brown, green and red propolis derived from fifferent geographic regions in Brazil. Plos One 8: 1-26. ), there was a high concentration of methanolic extracts in the plant parts, mainly in the leaves, in relation to the propolis extract. These data corroborate the results in this study, indicating that the leaves are an important source of phenolic compounds.

The levels of total phenols and total flavonoids in our study were higher than those reported by Lianhe et al. (2012)Lianhe Z, Xing H, Li W & Zhengxing C (2012) Physicochemical properties, chemical composition and antioxidant activity of Dalbergia odorifera T. Chen seed oil. Journal of the American Oil Chemists' Society 89: 883-890. and Chaitra et al. (2015)Chaitra S, Kumar NN, Shalini P & Sharu Raj KM (2015) In vitro antioxidant activity of methanolic extracts of Dalbergia paniculata Roxb. International Journal of Pharmacy and Pharmaceutical Sciences 5: 938-944. in other species of the genus Dalbergia and in red propolis. This fact can be associated with several factors, namely sample extraction and preparation procedures, seasonal variations, storage and quality of raw material (Rasheed et al. 2012Rasheed NMA, Nagaiah K, Goud PR & Sharma VUM (2012) Chemical marker compounds and treir essential role in quality controlo f herbal medicines. Annals of Phytomedicine 1: 1-8. ).

Identification of chemical compounds by LC/MS

The chromatographic profile of extracts of stems and leaves of D. ecastaphyllum recorded at 280 nm and identification based on the deprotonated molecule, its fragmentations (MS) and comparison with molecular masses described in the literature are summarized in Table 2.

Thumbnail

Table 2
Identification of chemical compounds in samples of Dalbergia ecastaphyllum stems and leaves using LC / MS. L = Leaf; S = Stem.

The LC/MS method allowed identification of 49 chemical compounds, of which 38% was compounds found exclusive in the stem, 30% in the leaf and 32% common to the samples. These compounds are distributed in 38 flavonoids and have phenolic acids. An organic acid (malic acid) was also detected in the leaf and aldehyde (4-hydroxybenzaldehyde) was observed in the stem. Among the flavonoids, the highest number of compounds are in the flavonols class (n = 18), followed by isoflavonoids (n = 8), flavanones (n = 5), flavanol (n = 3), flavones and with less representation to chalcone (n = 1) and dihydrochalcone (n = 1). Only the flavones (derived from luteolin) were assimilated into the leaves. Isoflavonoids, formononetin, and medicarpin were present both in the stem and in the leaves.

Donnelly et al. (1973)Donnelly DMX, Keenan PJ & Prendergast JP (1973) Isoflavonoids of Dalbergia ecastophyllum. Phytochemistry 12: 1157-1161. and Matos et al. (1975)Matos FJA, Gottlieb OR & Andrade CHS (1975) Flavonoids from Dalbergia ecastophyllum. Phytochemistry 14: 825-826., analyzing the content of flavonoids in woody extract of the species D. ecastaphyllum, recorded the compounds formononetin (C₁₆H₁₂O₄), isoliquiritigenin (C₁₅H₁₂O₄), daidzein (C₁₅H₁₀O₄), vestitol (C₁₆H₁₆O₄), which were also found in this study. Few investigations have been carried out exclusively on D. ecastaphyllum and most are related in a comparative way to its resin with the chemical composition of red propolis. Several studies on chemical compositions show that resin of D. ecastaphyllum is the main raw material for Brazilian red propolis, mainly due to the presence of compounds like formononetin (m / z 267), biochanin A (m / z 283), pinocembrin (m / z 255), daidzein (m / z 253), medicarpin (m / z 269), isoliquiritigenin (m / z 255), (Daugsch et al. 2008Daugsch A, Morais CS, Fort P & Park YK (2008) Brazilian red própolis - chemical composition and botanical origin. Evidence-based complementary and alternative medicine 5: 435-441. ; Piccinelli et al. 2011Piccinelli AL, Lotti C, Campone L, Cuesta-Rubio O, Fernandez MC & Rastrelli L (2011) Cuban and Brazilian red propolis: botanical origin and comparative analysis by high-performance liquid chromatography-photodiode array detection/electrospray ionization tandem mass spectrometry. Journal of Agricultural and Food Chemistry 59: 6484-6491.; López et al. 2014López BGC, Schmidt EM, Eberlin MN & Sawaya ACHF (2014) Phytochemical markers of different types of red propolis. Food Chemistry 146: 174-180.; Mendonça-Melo et al. 2017Mendonça-Melo L, Mota E, Lopez B, Sawaya A, Freitas L, Jain S, Batista M & Araújo E (2017) Chemical and genetic similarity between Dalbergia ecastaphyllum and red propolis from the Northeastern Brazil. Journal of Apicultural Research 56: 1-8. ).

In the other species of the genus Dalbergia, studies reported isoflavonoid fomononetin in the shell of D. melanoxylon (Mutai et al. 2013Mutai P, Heydenreich M, Thoithi G, Mugumbate G, Chibale K & Yenesew A (2013) 3-Hydroxyisoflavanones from the stem bark of Dalbergia melanoxylon: Isolation, antimycobacterial evaluation and molecular docking studies. Phytochemistry Letters 6: 671-675. ), pinocenbrin, liquiritigenin, galangin, naringenin and isoquiritigenin in ethanolic extracts of D. conchichinensis (Liu et al. 2016Liu R, Wen X, Shao F, Zhang P, Huang H & Zhang S (2016) Flavonoids from heartwood of Dalbergia cochinchinensis. Chinese Herbal Medicines 8: 89-93.). biochanin A and genistein were the main compounds present in the leaves of D. odorifera (Zhang et al. 2011Zhang DY, Zu YJ, Fu YJ, Luo M, Gu CB, Wang W & Yao XH (2011) Negative pressure cavitation extraction and antioxidant activity of biochanin A and genistein from the leaves of Dalbergia odorifera T. Separation and Purification Technology 83: 91-99.); however, in our study, biochanin A was only recorded in the stem. Catechin, epicatechin, luteolin, naringenin, quercetin, daidzein and the caffeic acid are considered antioxidant compounds (Cömert & Gökmen 2018Cömert ED & Gökmen V (2018) Evolution of food antioxidants as a core topic of food science for a century. Food Research International 105: 76-93. ).

In the stem and leaf samples of D. ecastaphyllum, promising compounds for human health were identified, such as formononetin, which has a potential effect on dermatitis attenuation (Li et al. 2018aLi L, Wang Y, Wang X, Tao Y, Bao K, Hua Y, Jiang G & Hong M (2018) Formononetin attenuated allergic diseases through inhibition of epithelial-derived cytokines by regulating E-cadherin. Clinical Immunology 195: 67-76a.), inhibition of cancer cell proliferation and metastasis (Zhang et al. 2018Zhang J, Liu L, Wang J, Ren B, Zhang L & Li W (2018) Formononetin, an isoflavone from Astragalus membranaceus inhibits proliferation and metastasis of ovarian cancer cells. Journal of Ethnopharmacology 221: 91-99.), neuroprotective (Li et al. 2018bLi Z, Zeng G, Zheng X, Wang W, Ling Y, Tang H & Zhang J (2018) Neuroprotective effect of formononetin against TBI in rats via suppressing inflammatory reaction in cortical neurons. Biomed. Pharmacotherapy 106: 349-354b.) and antibactericidal properties (Mutai et al. 2015Mutai P, Pavadai E, Wiid I, Ngwane A, Baker B & Chibale K (2015) Synthesis, antimycobacterial evaluation and pharmacophore modeling of analogues of the natural product formononetin. Bioorganic & Medicinal Chemistry Letters 25: 2510-2513. ). Pinocembrin suppressed autophagy in melanoma cells (Zheng et al. 2018Zheng Y, Wang K, Wu Y, Chen Y, Chen X, Hu CW & Hu F (2018) Pinocembrin induces ER stress mediated apoptosis and suppresses autophagy in melanoma cells. Cancer Letters 431: 31-42. ), demonstrating a protective effect on ischemia-induced brain injury (Tao et al. 2018Tao J, Shen C, Yanchun S, Chen W & Gangfeng Y (2018) Neuroprotective effects of pinocembrin on ischemia/reperfusion-induced brain injury by inhibiting autophagy. Biomedicine & Pharmacotherapy 106: 1003-1010.) and neurovascular area with deficits related to Alzheimer's (Liu et al. 2014Liu R, Li JZ, Song JK, Zhou D, Huang C, Bai XY, Xie T, Zhang X, Li YJ, Wu CX, Zhang L, Li L, Zhang TT & Du GH (2014) Pinocembrin improves cognition and protects the neurovascular unit in Alzheimer related deficits. Neurobiology of Aging 35: 1275-1285. ). Medicarpin could be used as a chemopreventive or cytotoxic agent for chemotherapeutic agents in resistant cancer cells (Gatouillat et al. 2015Gatouillat G, Magid AA, Bertin, E, Morjani H, Lavaud C & Madoulet C (2015) Medicarpin and millepurpan, two flavonoids isolated from Medicago sativa, induce apoptosis and overcome multidrug resistance in leukemia P388 cells. Phytomedicine 22: 1186-1194.). Rutin reduced plasma and glucose levels associated to diabetes, it prevented degenerative changes in the heart, anti-inflammatory effect against intestinal diseases, anti-allergic properties against rhinitis and dermatitis, anti-tumor and antimicrobial features. These activities are linked mainly to the high antioxidant property of this compound (Gullón et al. 2017Gullón B, Lú-Chau TA, Moreira MT, Lema JM & Eibes G (2017) Rutin: a review on extraction, identiﬁcation and puriﬁcation methods, biological activities and approaches to enhance its bioavailability. Trends in Food Science & Technology 67: 220-235.).

Antioxidant Activities

Antioxidants are substances capable of preventing and fighting oxidative damage caused by free radicals (Alves et al. 2010Alves CQ, David JM, David JP, Bahia MV & Aguiar RM (2010) Métodos para determinação de atividade antioxidante in vitro em substratos orgânicos. Química Nova 33: 2202-2210.). Excess of these radicals could cause deleterious damage to mitochondria (Mailloux et al. 2014Mailloux RJ, Jin X & Willmore WG (2014) Redox regulation of mitochondrial function with emphasis on cysteine oxidation reactions. Redox Biology 19: 123-139. ), plasma membrane (Neto & Cordeiro 2016Neto AJP & Cordeiro RM (2016) Molecular simulations of the effects of phospholipid and cholesterol peroxidation on lipid membrane properties. Biochimica et Biophysica Acta 1858: 2191-2198. ), and DNA deoxyribonucleic acid (Citron et al. 2016Citron BA, Ameenuddin S, Uchida K, Suo WZ, Santacruz K & Festoff BW (2016) Membrane lipid peroxidation in neurodegeneration: role of thrombin and proteinase-activated receptor-1. Brain Research 15: 10-17.), triggering loss of cellular homeostasis and several pathogenic diseases (Alves et al. 2010Alves CQ, David JM, David JP, Bahia MV & Aguiar RM (2010) Métodos para determinação de atividade antioxidante in vitro em substratos orgânicos. Química Nova 33: 2202-2210.).

Secondary metabolites produced by plants are sources of active principles with potential to block free radicals. They are of interest in the production of drugs, nutraceuticals, functional foods and food additives (Atanasov et al. 2015Atanasov AG, Waltenberger B, Pferschy-Wenzig EM, Linder T, Wawrosch C, Uhrin P, Temml V, Wang L, Schwaiger S, Heiss EH, Rollinger JM, Schuster D, Breuss JM, Bochkov V, Mihovilovic MD, Kopp B, Bauer R, Dirsch VM & Stuppner H (2015) Discovery and resupply of pharmacologically active plant-derived natural products: a review. Biotechnology Advances 33: 1582-1614.).

The methanolic extract of the leaves analyzed revealed a greater power reduction of the DPPH radical (33.53 ± 2.14 µg / mL, Mann-Whitney test, p = 0.00001) (Fig. 2c) and better results for the β-carotene bleaching (70.37 ± 1.36%, Student t-test, p = 0.0034) (Fig. 2d), compared to the stems. Reference substances, butyl hydroxyanisole (BHA) (11 ± 0.001 µg / mL) and ascorbic acid (22 ± 0.002 µg / mL), have shown to be more efficient in the reduction (p < 0.05) of DPPH. The β-carotene bleaching test showed that the antioxidant activity of BHA (95.62 ± 1.15%) was higher than in our extracts, while ascorbic acid was less expressive (43.63 ± 0. 95%).

The antioxidant activity of the hydroalcoholic extract of D. monetaria bark at a concentration of 5.46 ± 0.17 µg/mL presented better DPPH sequestering efficacy than in this study (Martins et al. 2016Martins FJ, Caneschi CA, Vieira JLF, Barbosa W & Raposo NRB (2016) Antioxidant activity and potential photoprotective from amazon native flora extracts. Journal of Photochemistry and Photobiology B: Biology 161: 34-39.). Ganga et al. (2012)Ganga RB, Madhu KP & Vijaya RAD (2012) Investigation of antioxidant and anti-inflammatory activity of leaves of Dalbergia paniculata (Roxb). Asian Pacific Journal of Tropical Medicine 5: 455-458. observed that the free radical sequestering activity of the methanolic extract of D. paniculata leaf is related to the anti-inflammatory action tested in rat edema. For the antiradicalar effect (DPPH), the EC50 value (70.6 µg/mL) found by these authors needed a higher concentration of methanolic extract of leaves of D. paniculata than the methanolic extract of leaves of D. ecastaphyllum (33 µg/ml).

The carotenoid β-Carotene helps in the inhibition of cellular lipid auto-oxidation; however, at high amounts of reactive oxygen species, it can undergo oxidation. The β-carotene/linoleic acid system allows evaluating the ability of an antioxidant to protect β-carotene during the peroxidation of linoleic acid (Alves et al. 2010Alves CQ, David JM, David JP, Bahia MV & Aguiar RM (2010) Métodos para determinação de atividade antioxidante in vitro em substratos orgânicos. Química Nova 33: 2202-2210.). Souza et al. (2015)Souza AHP, Corrêa RCG, Barros L, Calhelha RC, Santos-Buelga C, Peralta RM, Bracht A, Matsushita M & Ferreira ICFR (2015) Phytochemicals and biactive properties of Ile paraguariensis: na in-vitro comparatives study between the whole plant, leaves and stems. Food Research International 78: 286-294. also observed that extracts from leaves of I. paraguariensis prevented β-carotene degradation better than the stem extracts did.

The results of the multivariate analysis of canonical correlation show that the first canonical pair was significant (p < 0.01) and with a high correlation value, which was used to interpret the data (Tab. 3). The results show that 89% of the variance between the groups of characteristics are explained by the canonical function 1. Therefore, the contents of phenols and flavonoids presented a positive correlation with the β-carotene/linoleic acid method and a high negative correlation with DPPH. These results indicate, respectively, that the higher the phenolic compounds content, the greater the inhibition of lipid peroxidation and the lower the concentration of antioxidant in free radical sequestration DPPH.

Thumbnail

Table 3
Canonical correlation and canonical pairs between the variables (phenols, flavonoids and β-carotene / linoleic acid and DPPH) of the groups, stem and leaf of Dalbergia ecastaphyllum.

^a = 1,1- Difenyl-2-picrylhydrazyl; ** = p < 0.001; ^ns = not significant (p < 0.05); ^b = Canonical correlation; ^c = Approximate value of the statistic F; ^d = Level of significance.

The A canonical correlation analysis corroborates observations that the leaves showed better antioxidant activity, regardless of the method used, in comparison with the stems, which can be explained by the high content of phenolic compounds (Fig. 2a,b), the main secondary compounds of plants to control or delay the damage caused by free radicals to genetic material or lipid peroxidation (Farzaneh & Oliveira 2015Farzaneh V & Oliveira IS (2015) A review of the health benefit potentials of herbal plant infusions and their mechanism of action. Industrial Crops and Products 65: 247-258.).

Conclusion

The stems and leaves of D. ecastaphyllum presented high levels of phenolic compounds and lipid contents with valuable acids, such as the linoleic and linolenic acids (omega family), respectively. The presence of the flavonoids formononetin, pinocembrin, kaempferol, rutin, naringenin and medicarpin among others characterizes chemical compositions that deserve attention, due to the versatility of pharmacological properties reported by the literature and antioxidant activity pointed out in this study. However, leaf samples showed significant higher results for total phenolic compounds and antioxidant activity when compared to stem samples. The absence of pathogenic bacteria in the samples is also a positive result.

The results indicate that the stems and leaves of D. ecastaphyllum have biological properties. Leaves are particularly better for functional food formulations and as natural antioxidant.

Acknowledgements

The authors thank the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) by the sandwich doctorate (SWE) within the scope of the MEC/MCTI/CAPES/CNPq/FAPs nº 09/2014 - Special Visiting Researcher; the Conselho Nacional de Desenvolvimento Tecnológico e Científico (CNPq); the Fundação de Amparo à Pesquisa do Estado da Bahia (FAPESB / PET 0022/2012); the Insecta Research Group of the Universidade Federal do Recôncavo da Bahia (UFRB). The Cooperativa de Apicultores de Canavieiras (COAPER) collaboration in the acquisition of samples. The Instituto Politécnico de Bragança (IPB-PT), the strategic programmer UID/BIA/04050/2013(POCI-01-0145-FEDER-007569) funded by national funds through the Fundação para a Ciência e a Tecnologia (FCT), Portugal and by the European Regional Development Fund (ERDF) through the COMPETE2020-Programa Operacional Competitividade e Internacionalização (POCI).

References

Adebiyia OE, Olayemi FO, Ning-Hua T & Guang-Zhi Z (2017) In vitro antioxidant activity, total phenolic and flavonoid contents of ethanol extract of stem and leaf of Grewia carpinifolia Beni-Suef University Journal of Basic and Applied Sciences 6: 10-14.
Alencar SM, Oldoni TLC, Castro ML, Cabral ISR, Costa-Neto CM, Cury JA, Rosalen PL & Ikegaki M (2007) Chemical composition and biological activity of a new type of Brazilian propolis: red própolis. Journal of Ethnopharmacology 113: 278-283.
Alves CQ, David JM, David JP, Bahia MV & Aguiar RM (2010) Métodos para determinação de atividade antioxidante in vitro em substratos orgânicos. Química Nova 33: 2202-2210.
AOAC (2005) Microbiological methods. In: Official methods of analysis. 16^th ed. Association of Official Analytical Chemists, Arlington. 246p.
Atanasov AG, Waltenberger B, Pferschy-Wenzig EM, Linder T, Wawrosch C, Uhrin P, Temml V, Wang L, Schwaiger S, Heiss EH, Rollinger JM, Schuster D, Breuss JM, Bochkov V, Mihovilovic MD, Kopp B, Bauer R, Dirsch VM & Stuppner H (2015) Discovery and resupply of pharmacologically active plant-derived natural products: a review. Biotechnology Advances 33: 1582-1614.
Barros L, Pereira E, Calhelha RC, Dueñas M, Carvalho AM, Santos-Buelga C & Ferreira ICFR (2013) Bioactivity and chemical characterization in hydrophilic and lipophilic compounds of Chenopodium ambrosioides L. Journal of Functional Foods 5: 1732-1740.
Bennett RW & Lancette GA (2001) Staphylococcus aureus Ch.12, rev. Jan. 2001. In: FDA bacteriological analytical manual, 8^th ed. rev. AOAC International, Gaitherburg. Available at <http://cfsan.fda.gov/~ebam/bam-12.html>. Access in Jan 2019.
» http://cfsan.fda.gov/~ebam/bam-12.html
Bohrer CBA, Dantas HGR, Gronemberger FM, Vincens RS & Andrade SF (2009) Mapeamento de vegetação e do uso do solo no centro de diversidade vegetal de Cabo Frio, Rio de Janeiro, Brasil. Rodriguésia 60: 1-23.
Brasil - Ministério da Saúde - Agência Nacional de Vigilância Sanitária (2010) Farmacopeia brasileira. Vol 2. Anvisa, Brasília. 546p.
Calder PC (2015) Functional roles of fatty acids and their effects on human health. Journal of Parenteral and Enteral Nutrition 39: 1-15.
Carta G, Murru E, Banni S & Manca C (2017) Palmitic acid: physiological role, metabolism and nutritional implications. Frontiers in Physiology 8: 1-14.
Carvalho AM (1997) A synopsis of the genus Dalbergia (Fabaceae: Dalbergieae) in Brazil. Brittonia 49: 87-100.
Chaitra S, Kumar NN, Shalini P & Sharu Raj KM (2015) In vitro antioxidant activity of methanolic extracts of Dalbergia paniculata Roxb. International Journal of Pharmacy and Pharmaceutical Sciences 5: 938-944.
Cheurfa M & Allem R (2015) Study of hypocholesterolemic activity of Algerian Pistacia lentiscus leaves extracts in vivo Revista Brasileira de Farmacognosia 25: 142-144.
Citron BA, Ameenuddin S, Uchida K, Suo WZ, Santacruz K & Festoff BW (2016) Membrane lipid peroxidation in neurodegeneration: role of thrombin and proteinase-activated receptor-1. Brain Research 15: 10-17.
Cömert ED & Gökmen V (2018) Evolution of food antioxidants as a core topic of food science for a century. Food Research International 105: 76-93.
Daugsch A, Morais CS, Fort P & Park YK (2008) Brazilian red própolis - chemical composition and botanical origin. Evidence-based complementary and alternative medicine 5: 435-441.
Department of Health and Social Security (1994) Nutritional aspects of cardiovascular disease. Report on health and social subjects no 46. HMSO Her Majesty's Stationer Office, London. 178p.
De-Melo AAM, Estevinho MLMF & Almeida-Muradian LB (2015) A diagnosis of the microbiological quality of dehydrated bee-pollen produced in Brazil. Letters in Applied Microbiology 61: 477-483.
Donnelly DMX, Keenan PJ & Prendergast JP (1973) Isoflavonoids of Dalbergia ecastophyllum Phytochemistry 12: 1157-1161.
Falcão SI, Tomás A, Vale N, Gomes P, Freire C & Vilas-Boas M (2013) Phenolic quantification and botanical origin of Portuguese propolis. Industrial Crops and Products 49: 805-812.
Farzaneh V & Oliveira IS (2015) A review of the health benefit potentials of herbal plant infusions and their mechanism of action. Industrial Crops and Products 65: 247-258.
Ganga RB, Madhu KP & Vijaya RAD (2012) Investigation of antioxidant and anti-inflammatory activity of leaves of Dalbergia paniculata (Roxb). Asian Pacific Journal of Tropical Medicine 5: 455-458.
Gatouillat G, Magid AA, Bertin, E, Morjani H, Lavaud C & Madoulet C (2015) Medicarpin and millepurpan, two flavonoids isolated from Medicago sativa, induce apoptosis and overcome multidrug resistance in leukemia P388 cells. Phytomedicine 22: 1186-1194.
Ge L, Gordon JS, Hsuan C, Stenn K & Prouty SM (2003) Identification of the delta-6 desaturase of human sebaceous glands: expression and enzyme activity. Journal of Investigative Dermatology 120: 707-714.
Gullón B, Lú-Chau TA, Moreira MT, Lema JM & Eibes G (2017) Rutin: a review on extraction, identiﬁcation and puriﬁcation methods, biological activities and approaches to enhance its bioavailability. Trends in Food Science & Technology 67: 220-235.
Guedes GMM, Albuquerque RS, Soares-Maciel RS, Freitas MA, Silva VA, Lima EO, Lima MA Cunha EVL & Coutinho HDM (2014) Isolation of phytosterols of Dalbergia ecastophyllum (L.) Taub. (Leguminosae) and modulation of antibiotic resistance by a possible membrane effect. Arabian Journal of Chemistry: 1-5.
Huang L, Gao X, Liu M, Du G, Guo J & Ntakirutimana T (2012) Correlation among soil microorganisms, soil enzyme activities, and removal rates of pollutants in three constructed wetlands purifying micro-polluted river water. Ecological Engineering 46: 98-106.
ISO 15213 (2003) Microbiology of food and animal feeding stuffs - Horizontal method for the enumeration of sulfite-reducing bacteria growing under anaerobic conditions. International Standards Organization, Winterthur. 12p.
ISO 21527-2 (2008) Microbiology of food and animal feeding stuffs - horizontal method for the enumeration of yeasts and moulds - part 2: colony count technique in products with water activity less than or equal to 0.95. International Standards Organization, Winterthur. 17p.
Johnson RA & Wichern DW (1992) Applied multivariate statistical analysis. 3^rd ed. Prentice-Hall, New Jersey. 642p.
Li L, Wang Y, Wang X, Tao Y, Bao K, Hua Y, Jiang G & Hong M (2018) Formononetin attenuated allergic diseases through inhibition of epithelial-derived cytokines by regulating E-cadherin. Clinical Immunology 195: 67-76a.
Li Z, Zeng G, Zheng X, Wang W, Ling Y, Tang H & Zhang J (2018) Neuroprotective effect of formononetin against TBI in rats via suppressing inflammatory reaction in cortical neurons. Biomed. Pharmacotherapy 106: 349-354b.
Lianhe Z, Xing H, Li W & Zhengxing C (2012) Physicochemical properties, chemical composition and antioxidant activity of Dalbergia odorifera T. Chen seed oil. Journal of the American Oil Chemists' Society 89: 883-890.
Lima HC (2015). Dalbergia. In: Lista de Espécies da Flora do Brasil. Instituto de Pesquisas Jardim Botânico do Rio de Janeiro. Disponivel em <http://floradobrasil.jbrj.gov.br/jabot/floradobrasil/FB22908>. Acesso em mai 2018.
» http://floradobrasil.jbrj.gov.br/jabot/floradobrasil/FB22908
Liu S, Lin J, Hu C, Shen B, Chen T, Chang Y, Shih C & Yang D (2017) Phenolic compositions and antioxidant attributes of leaves and stems from three inbred varieties of Lycium chinense Miller harvested at various times. Food Chemistry 215: 284-291.
Liu R, Li JZ, Song JK, Zhou D, Huang C, Bai XY, Xie T, Zhang X, Li YJ, Wu CX, Zhang L, Li L, Zhang TT & Du GH (2014) Pinocembrin improves cognition and protects the neurovascular unit in Alzheimer related deficits. Neurobiology of Aging 35: 1275-1285.
Liu R, Wen X, Shao F, Zhang P, Huang H & Zhang S (2016) Flavonoids from heartwood of Dalbergia cochinchinensis Chinese Herbal Medicines 8: 89-93.
López BGC, Schmidt EM, Eberlin MN & Sawaya ACHF (2014) Phytochemical markers of different types of red propolis. Food Chemistry 146: 174-180.
Machado BAS, Silva RPD, Barreto GA, Costa SS, Silva DF, Brandão HN, Rocha JLC, Dellagostin, OA, Henriques JAP, Umsza-Guez MA & Padilha FF (2016) Chemical composition and biological activity of extracts obtained by supercritical extraction and ethanolic extraction of brown, green and red propolis derived from fifferent geographic regions in Brazil. Plos One 8: 1-26.
Mailloux RJ, Jin X & Willmore WG (2014) Redox regulation of mitochondrial function with emphasis on cysteine oxidation reactions. Redox Biology 19: 123-139.
Martins FJ, Caneschi CA, Vieira JLF, Barbosa W & Raposo NRB (2016) Antioxidant activity and potential photoprotective from amazon native flora extracts. Journal of Photochemistry and Photobiology B: Biology 161: 34-39.
Matos FJA, Gottlieb OR & Andrade CHS (1975) Flavonoids from Dalbergia ecastophyllum Phytochemistry 14: 825-826.
Mendonça-Melo L, Mota E, Lopez B, Sawaya A, Freitas L, Jain S, Batista M & Araújo E (2017) Chemical and genetic similarity between Dalbergia ecastaphyllum and red propolis from the Northeastern Brazil. Journal of Apicultural Research 56: 1-8.
Mutai P, Heydenreich M, Thoithi G, Mugumbate G, Chibale K & Yenesew A (2013) 3-Hydroxyisoflavanones from the stem bark of Dalbergia melanoxylon: Isolation, antimycobacterial evaluation and molecular docking studies. Phytochemistry Letters 6: 671-675.
Mutai P, Pavadai E, Wiid I, Ngwane A, Baker B & Chibale K (2015) Synthesis, antimycobacterial evaluation and pharmacophore modeling of analogues of the natural product formononetin. Bioorganic & Medicinal Chemistry Letters 25: 2510-2513.
Neto AJP & Cordeiro RM (2016) Molecular simulations of the effects of phospholipid and cholesterol peroxidation on lipid membrane properties. Biochimica et Biophysica Acta 1858: 2191-2198.
Park YK, Ikegari M, Abreu JAS & Alcici NMF (1998) Estudo da preparação dos extratos de própolis e suas aplicações. Ciência e Tecnologia de Alimentos 18: 313-318.
Piccinelli AL, Lotti C, Campone L, Cuesta-Rubio O, Fernandez MC & Rastrelli L (2011) Cuban and Brazilian red propolis: botanical origin and comparative analysis by high-performance liquid chromatography-photodiode array detection/electrospray ionization tandem mass spectrometry. Journal of Agricultural and Food Chemistry 59: 6484-6491.
Rasheed NMA, Nagaiah K, Goud PR & Sharma VUM (2012) Chemical marker compounds and treir essential role in quality controlo f herbal medicines. Annals of Phytomedicine 1: 1-8.
Rufatto LC, Santos DA, Marinho F, Henriques JAP, Ely MR & Moura S (2017) Red propolis: chemical composition and pharmacological activity. Asian Pacific Journal of Tropical Biomedicine 7: 591-598.
Saha S, Anisuzzman M, Islam MK, Mondal H & Talukder C (2013) Antibacterial and cytotoxic potential of Dalbergia spinosa Roxb. leaves. International Journal of Pharmaceutical Sciences Review and Research 4: 512-515.
Santos-Silva J, Bessa RJB & Santos-Silva F (2002) Effect of genotype, feeding system and slaughter weight on the quality of light lambs. II. Fatty acid composition of meat. Livestock Production Science 77: 187-194.
Silva N, Junqueira VCA, Silveira NFA, Taniwaki MH, Santos RFS & Gomes RAR (2010) Manual de métodos de análises microbiológicas de alimentos e água. 4^a ed. Varela, São Paulo. 632p.
Singleton VL, Orthofer R & Lamuela-Raventos RM (1999) Analysis of total phenols and other oxidation substrates and antioxidants by means of Folin-Ciocalteu reagent. Methods in Enzymology 299: 152-178.
Souza AHP, Corrêa RCG, Barros L, Calhelha RC, Santos-Buelga C, Peralta RM, Bracht A, Matsushita M & Ferreira ICFR (2015) Phytochemicals and biactive properties of Ile paraguariensis: na in-vitro comparatives study between the whole plant, leaves and stems. Food Research International 78: 286-294.
Tao J, Shen C, Yanchun S, Chen W & Gangfeng Y (2018) Neuroprotective effects of pinocembrin on ischemia/reperfusion-induced brain injury by inhibiting autophagy. Biomedicine & Pharmacotherapy 106: 1003-1010.
Toghueo RMK, Zabalgogeazcoa I, Vázquez de Aldana BR & Boyom FF (2017) Enzymatic activity of endophytic fungi from the medicinal plants Terminalia catappa, Terminalia mantaly and Cananga odorata South African Journal of Botany 109: 146-153.
Ulbricht TLV & Southgate DAT (1991) Coronary heart disease: seven dietary factors. The Lancet 19: 985-992.
Zhang DY, Zu YJ, Fu YJ, Luo M, Gu CB, Wang W & Yao XH (2011) Negative pressure cavitation extraction and antioxidant activity of biochanin A and genistein from the leaves of Dalbergia odorifera T. Separation and Purification Technology 83: 91-99.
Zhang J, Liu L, Wang J, Ren B, Zhang L & Li W (2018) Formononetin, an isoflavone from Astragalus membranaceus inhibits proliferation and metastasis of ovarian cancer cells. Journal of Ethnopharmacology 221: 91-99.
Zheng Y, Wang K, Wu Y, Chen Y, Chen X, Hu CW & Hu F (2018) Pinocembrin induces ER stress mediated apoptosis and suppresses autophagy in melanoma cells. Cancer Letters 431: 31-42.
Zhuang P, Wang W, Wang J, Zhang Y & Jiao J (2018) Polyunsaturated fatty acids intake, omega-6/omega-3 ratio and mortality: findings from two independent nationwide cohorts. Clinical Nutrition 38: 848-855.

Edited by

Area Editor: Dr. Danilo Oliveira

Publication Dates

Publication in this collection
13 July 2020
Date of issue
2020

History

Received
31 May 2019
Accepted
15 Aug 2019

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Adebiyia OE, Olayemi FO, Ning-Hua T & Guang-Zhi Z (2017) In vitro antioxidant activity, total phenolic and flavonoid contents of ethanol extract of stem and leaf of Grewia carpinifolia Beni-Suef University Journal of Basic and Applied Sciences 6: 10-14.

[2] Alencar SM, Oldoni TLC, Castro ML, Cabral ISR, Costa-Neto CM, Cury JA, Rosalen PL & Ikegaki M (2007) Chemical composition and biological activity of a new type of Brazilian propolis: red própolis. Journal of Ethnopharmacology 113: 278-283.

[3] Alves CQ, David JM, David JP, Bahia MV & Aguiar RM (2010) Métodos para determinação de atividade antioxidante in vitro em substratos orgânicos. Química Nova 33: 2202-2210.

[4] AOAC (2005) Microbiological methods. In: Official methods of analysis. 16^th ed. Association of Official Analytical Chemists, Arlington. 246p.

[5] Atanasov AG, Waltenberger B, Pferschy-Wenzig EM, Linder T, Wawrosch C, Uhrin P, Temml V, Wang L, Schwaiger S, Heiss EH, Rollinger JM, Schuster D, Breuss JM, Bochkov V, Mihovilovic MD, Kopp B, Bauer R, Dirsch VM & Stuppner H (2015) Discovery and resupply of pharmacologically active plant-derived natural products: a review. Biotechnology Advances 33: 1582-1614.

[6] Barros L, Pereira E, Calhelha RC, Dueñas M, Carvalho AM, Santos-Buelga C & Ferreira ICFR (2013) Bioactivity and chemical characterization in hydrophilic and lipophilic compounds of Chenopodium ambrosioides L. Journal of Functional Foods 5: 1732-1740.

[7] Bennett RW & Lancette GA (2001) Staphylococcus aureus Ch.12, rev. Jan. 2001. In: FDA bacteriological analytical manual, 8^th ed. rev. AOAC International, Gaitherburg. Available at <http://cfsan.fda.gov/~ebam/bam-12.html>. Access in Jan 2019.
» http://cfsan.fda.gov/~ebam/bam-12.html

[8] Bohrer CBA, Dantas HGR, Gronemberger FM, Vincens RS & Andrade SF (2009) Mapeamento de vegetação e do uso do solo no centro de diversidade vegetal de Cabo Frio, Rio de Janeiro, Brasil. Rodriguésia 60: 1-23.

[9] Brasil - Ministério da Saúde - Agência Nacional de Vigilância Sanitária (2010) Farmacopeia brasileira. Vol 2. Anvisa, Brasília. 546p.

[10] Calder PC (2015) Functional roles of fatty acids and their effects on human health. Journal of Parenteral and Enteral Nutrition 39: 1-15.

[11] Carta G, Murru E, Banni S & Manca C (2017) Palmitic acid: physiological role, metabolism and nutritional implications. Frontiers in Physiology 8: 1-14.

[12] Carvalho AM (1997) A synopsis of the genus Dalbergia (Fabaceae: Dalbergieae) in Brazil. Brittonia 49: 87-100.

[13] Chaitra S, Kumar NN, Shalini P & Sharu Raj KM (2015) In vitro antioxidant activity of methanolic extracts of Dalbergia paniculata Roxb. International Journal of Pharmacy and Pharmaceutical Sciences 5: 938-944.

[14] Cheurfa M & Allem R (2015) Study of hypocholesterolemic activity of Algerian Pistacia lentiscus leaves extracts in vivo Revista Brasileira de Farmacognosia 25: 142-144.

[15] Citron BA, Ameenuddin S, Uchida K, Suo WZ, Santacruz K & Festoff BW (2016) Membrane lipid peroxidation in neurodegeneration: role of thrombin and proteinase-activated receptor-1. Brain Research 15: 10-17.

[16] Cömert ED & Gökmen V (2018) Evolution of food antioxidants as a core topic of food science for a century. Food Research International 105: 76-93.

[17] Daugsch A, Morais CS, Fort P & Park YK (2008) Brazilian red própolis - chemical composition and botanical origin. Evidence-based complementary and alternative medicine 5: 435-441.

[18] Department of Health and Social Security (1994) Nutritional aspects of cardiovascular disease. Report on health and social subjects no 46. HMSO Her Majesty's Stationer Office, London. 178p.

[19] De-Melo AAM, Estevinho MLMF & Almeida-Muradian LB (2015) A diagnosis of the microbiological quality of dehydrated bee-pollen produced in Brazil. Letters in Applied Microbiology 61: 477-483.

[20] Donnelly DMX, Keenan PJ & Prendergast JP (1973) Isoflavonoids of Dalbergia ecastophyllum Phytochemistry 12: 1157-1161.

[21] Falcão SI, Tomás A, Vale N, Gomes P, Freire C & Vilas-Boas M (2013) Phenolic quantification and botanical origin of Portuguese propolis. Industrial Crops and Products 49: 805-812.

[22] Farzaneh V & Oliveira IS (2015) A review of the health benefit potentials of herbal plant infusions and their mechanism of action. Industrial Crops and Products 65: 247-258.

[23] Ganga RB, Madhu KP & Vijaya RAD (2012) Investigation of antioxidant and anti-inflammatory activity of leaves of Dalbergia paniculata (Roxb). Asian Pacific Journal of Tropical Medicine 5: 455-458.

[24] Gatouillat G, Magid AA, Bertin, E, Morjani H, Lavaud C & Madoulet C (2015) Medicarpin and millepurpan, two flavonoids isolated from Medicago sativa, induce apoptosis and overcome multidrug resistance in leukemia P388 cells. Phytomedicine 22: 1186-1194.

[25] Ge L, Gordon JS, Hsuan C, Stenn K & Prouty SM (2003) Identification of the delta-6 desaturase of human sebaceous glands: expression and enzyme activity. Journal of Investigative Dermatology 120: 707-714.

[26] Gullón B, Lú-Chau TA, Moreira MT, Lema JM & Eibes G (2017) Rutin: a review on extraction, identiﬁcation and puriﬁcation methods, biological activities and approaches to enhance its bioavailability. Trends in Food Science & Technology 67: 220-235.

[27] Guedes GMM, Albuquerque RS, Soares-Maciel RS, Freitas MA, Silva VA, Lima EO, Lima MA Cunha EVL & Coutinho HDM (2014) Isolation of phytosterols of Dalbergia ecastophyllum (L.) Taub. (Leguminosae) and modulation of antibiotic resistance by a possible membrane effect. Arabian Journal of Chemistry: 1-5.

[28] Huang L, Gao X, Liu M, Du G, Guo J & Ntakirutimana T (2012) Correlation among soil microorganisms, soil enzyme activities, and removal rates of pollutants in three constructed wetlands purifying micro-polluted river water. Ecological Engineering 46: 98-106.

[29] ISO 15213 (2003) Microbiology of food and animal feeding stuffs - Horizontal method for the enumeration of sulfite-reducing bacteria growing under anaerobic conditions. International Standards Organization, Winterthur. 12p.

[30] ISO 21527-2 (2008) Microbiology of food and animal feeding stuffs - horizontal method for the enumeration of yeasts and moulds - part 2: colony count technique in products with water activity less than or equal to 0.95. International Standards Organization, Winterthur. 17p.

[31] Johnson RA & Wichern DW (1992) Applied multivariate statistical analysis. 3^rd ed. Prentice-Hall, New Jersey. 642p.

[32] Li L, Wang Y, Wang X, Tao Y, Bao K, Hua Y, Jiang G & Hong M (2018) Formononetin attenuated allergic diseases through inhibition of epithelial-derived cytokines by regulating E-cadherin. Clinical Immunology 195: 67-76a.

[33] Li Z, Zeng G, Zheng X, Wang W, Ling Y, Tang H & Zhang J (2018) Neuroprotective effect of formononetin against TBI in rats via suppressing inflammatory reaction in cortical neurons. Biomed. Pharmacotherapy 106: 349-354b.

[34] Lianhe Z, Xing H, Li W & Zhengxing C (2012) Physicochemical properties, chemical composition and antioxidant activity of Dalbergia odorifera T. Chen seed oil. Journal of the American Oil Chemists' Society 89: 883-890.

[35] Lima HC (2015). Dalbergia. In: Lista de Espécies da Flora do Brasil. Instituto de Pesquisas Jardim Botânico do Rio de Janeiro. Disponivel em <http://floradobrasil.jbrj.gov.br/jabot/floradobrasil/FB22908>. Acesso em mai 2018.
» http://floradobrasil.jbrj.gov.br/jabot/floradobrasil/FB22908

[36] Liu S, Lin J, Hu C, Shen B, Chen T, Chang Y, Shih C & Yang D (2017) Phenolic compositions and antioxidant attributes of leaves and stems from three inbred varieties of Lycium chinense Miller harvested at various times. Food Chemistry 215: 284-291.

[37] Liu R, Li JZ, Song JK, Zhou D, Huang C, Bai XY, Xie T, Zhang X, Li YJ, Wu CX, Zhang L, Li L, Zhang TT & Du GH (2014) Pinocembrin improves cognition and protects the neurovascular unit in Alzheimer related deficits. Neurobiology of Aging 35: 1275-1285.

[38] Liu R, Wen X, Shao F, Zhang P, Huang H & Zhang S (2016) Flavonoids from heartwood of Dalbergia cochinchinensis Chinese Herbal Medicines 8: 89-93.

[39] López BGC, Schmidt EM, Eberlin MN & Sawaya ACHF (2014) Phytochemical markers of different types of red propolis. Food Chemistry 146: 174-180.

[40] Machado BAS, Silva RPD, Barreto GA, Costa SS, Silva DF, Brandão HN, Rocha JLC, Dellagostin, OA, Henriques JAP, Umsza-Guez MA & Padilha FF (2016) Chemical composition and biological activity of extracts obtained by supercritical extraction and ethanolic extraction of brown, green and red propolis derived from fifferent geographic regions in Brazil. Plos One 8: 1-26.

[41] Mailloux RJ, Jin X & Willmore WG (2014) Redox regulation of mitochondrial function with emphasis on cysteine oxidation reactions. Redox Biology 19: 123-139.

[42] Martins FJ, Caneschi CA, Vieira JLF, Barbosa W & Raposo NRB (2016) Antioxidant activity and potential photoprotective from amazon native flora extracts. Journal of Photochemistry and Photobiology B: Biology 161: 34-39.

[43] Matos FJA, Gottlieb OR & Andrade CHS (1975) Flavonoids from Dalbergia ecastophyllum Phytochemistry 14: 825-826.

[44] Mendonça-Melo L, Mota E, Lopez B, Sawaya A, Freitas L, Jain S, Batista M & Araújo E (2017) Chemical and genetic similarity between Dalbergia ecastaphyllum and red propolis from the Northeastern Brazil. Journal of Apicultural Research 56: 1-8.

[45] Mutai P, Heydenreich M, Thoithi G, Mugumbate G, Chibale K & Yenesew A (2013) 3-Hydroxyisoflavanones from the stem bark of Dalbergia melanoxylon: Isolation, antimycobacterial evaluation and molecular docking studies. Phytochemistry Letters 6: 671-675.

[46] Mutai P, Pavadai E, Wiid I, Ngwane A, Baker B & Chibale K (2015) Synthesis, antimycobacterial evaluation and pharmacophore modeling of analogues of the natural product formononetin. Bioorganic & Medicinal Chemistry Letters 25: 2510-2513.

[47] Neto AJP & Cordeiro RM (2016) Molecular simulations of the effects of phospholipid and cholesterol peroxidation on lipid membrane properties. Biochimica et Biophysica Acta 1858: 2191-2198.

[48] Park YK, Ikegari M, Abreu JAS & Alcici NMF (1998) Estudo da preparação dos extratos de própolis e suas aplicações. Ciência e Tecnologia de Alimentos 18: 313-318.

[49] Piccinelli AL, Lotti C, Campone L, Cuesta-Rubio O, Fernandez MC & Rastrelli L (2011) Cuban and Brazilian red propolis: botanical origin and comparative analysis by high-performance liquid chromatography-photodiode array detection/electrospray ionization tandem mass spectrometry. Journal of Agricultural and Food Chemistry 59: 6484-6491.

[50] Rasheed NMA, Nagaiah K, Goud PR & Sharma VUM (2012) Chemical marker compounds and treir essential role in quality controlo f herbal medicines. Annals of Phytomedicine 1: 1-8.

[51] Rufatto LC, Santos DA, Marinho F, Henriques JAP, Ely MR & Moura S (2017) Red propolis: chemical composition and pharmacological activity. Asian Pacific Journal of Tropical Biomedicine 7: 591-598.

[52] Saha S, Anisuzzman M, Islam MK, Mondal H & Talukder C (2013) Antibacterial and cytotoxic potential of Dalbergia spinosa Roxb. leaves. International Journal of Pharmaceutical Sciences Review and Research 4: 512-515.

[53] Santos-Silva J, Bessa RJB & Santos-Silva F (2002) Effect of genotype, feeding system and slaughter weight on the quality of light lambs. II. Fatty acid composition of meat. Livestock Production Science 77: 187-194.

[54] Silva N, Junqueira VCA, Silveira NFA, Taniwaki MH, Santos RFS & Gomes RAR (2010) Manual de métodos de análises microbiológicas de alimentos e água. 4^a ed. Varela, São Paulo. 632p.

[55] Singleton VL, Orthofer R & Lamuela-Raventos RM (1999) Analysis of total phenols and other oxidation substrates and antioxidants by means of Folin-Ciocalteu reagent. Methods in Enzymology 299: 152-178.

[56] Souza AHP, Corrêa RCG, Barros L, Calhelha RC, Santos-Buelga C, Peralta RM, Bracht A, Matsushita M & Ferreira ICFR (2015) Phytochemicals and biactive properties of Ile paraguariensis: na in-vitro comparatives study between the whole plant, leaves and stems. Food Research International 78: 286-294.

[57] Tao J, Shen C, Yanchun S, Chen W & Gangfeng Y (2018) Neuroprotective effects of pinocembrin on ischemia/reperfusion-induced brain injury by inhibiting autophagy. Biomedicine & Pharmacotherapy 106: 1003-1010.

[58] Toghueo RMK, Zabalgogeazcoa I, Vázquez de Aldana BR & Boyom FF (2017) Enzymatic activity of endophytic fungi from the medicinal plants Terminalia catappa, Terminalia mantaly and Cananga odorata South African Journal of Botany 109: 146-153.

[59] Ulbricht TLV & Southgate DAT (1991) Coronary heart disease: seven dietary factors. The Lancet 19: 985-992.

[60] Zhang DY, Zu YJ, Fu YJ, Luo M, Gu CB, Wang W & Yao XH (2011) Negative pressure cavitation extraction and antioxidant activity of biochanin A and genistein from the leaves of Dalbergia odorifera T. Separation and Purification Technology 83: 91-99.

[61] Zhang J, Liu L, Wang J, Ren B, Zhang L & Li W (2018) Formononetin, an isoflavone from Astragalus membranaceus inhibits proliferation and metastasis of ovarian cancer cells. Journal of Ethnopharmacology 221: 91-99.

[62] Zheng Y, Wang K, Wu Y, Chen Y, Chen X, Hu CW & Hu F (2018) Pinocembrin induces ER stress mediated apoptosis and suppresses autophagy in melanoma cells. Cancer Letters 431: 31-42.

[63] Zhuang P, Wang W, Wang J, Zhang Y & Jiao J (2018) Polyunsaturated fatty acids intake, omega-6/omega-3 ratio and mortality: findings from two independent nationwide cohorts. Clinical Nutrition 38: 848-855.

Fatty acids	Stems	Leaves
Fatty acids	Mean (%) ± SD^a	Mean (%) ± SD^a
Caprylic Acid (C8:0)	4.21 ± 1.20*	2.57 ± 0.70
Lauric Acid (C12:0)	0.69 ± 0.40*	0.25 ± 0.07
Myristic Acid (C14:0)	1.10 ± 0.23	0.96 ± 0.11
Pentadecanoic Acid (C15:0)	0.65 ± 0.10*	0.15 ± 0.04
Cis-10-Pentadecenoic Acid (C15:1 CIS-10)	0.34 ± 0.11	NF^b
Palmitic Acid (C16:0)	38.19 ± 4.47	37.68 ± 2.72
Heptadecanoic Acid (C17:0)	2.75 ± 0.57*	1.04 ± 0.24
Cis-10-Heptadecenoic Acid (C17:1 CIS-10)	NF	0.05 ± 0.03
Stearic Acid (C18:0)	6.92 ± 1.35*	5.26 ± 0.96
Oleic Acid (C18:1n9ct)	2.50 ± 1.51	3.07 ± 0.65
Linolelaidic Acid (C18:2n6t)	0.90 ± 0.35	NF
Linoleic Acid (C18:2n6c)	24.50 ± 5.16*	4.22 ± 1.41
Linolenic Acid (C18:3n3)	11.02 ± 2.29	41.54 ± 4.06*
Arachinic Acid (C20:0)	1.59 ± 0.65*	0.27 ± 0.10
Cis-11,14-Eicosadienoic Acid (C20:2 CIS)	0.51 ± 0.14	NF
Cis-8,11,14-Eicosatrienoic Acid (C20:3n6)	0.38 ± 0.23	NF
Eicosatrienoic Acid (C20:3n3)	NF	0.30 ± 0.20
Behenic Acid (C22:0)	0.97 ± 0.53*	0.12 ± 0.06
Tricosanoic Acid (C23:0)	0.60 ± 0.32*	0.14 ± 0.07
Lignoceric Acid (C24:0)	1.14 ± 0.82*	0.39 ± 0.13
Nervonic Acid (C24:1)	1.03 ± 0.51	NF
Sums and proportions of fatty acids
SAT^c	58.81 ± 7.65*	50.82 ± 4.28
MUFA^d	3.87 ± 1.75	3.11 ± 0.64
PUFA^e	37.32 ± 6.49	46.06 ± 4.43*
Total	100	100
n-6^f	25.78 ± 5.16*	4.22 ± 1.41
n-3^g	11.02 ± 2.29	41.84 ± 4.06*
PUFA:SAT^h	0.65 ± 0.21	0.92 ± 0.15*
n-6:n-3ⁱ	2.23 ± 0.40*	0.10 ± 0.03
Nutritional quality indexes of the lipid fraction
AI^j	1.15 ± 0.30*	0.86 ± 0.08
TI^k	1.02 ± 0.30*	0.32 ± 0.03
HH^l	1.00 ± 0.32	1.27 ± 0.14*

RT	[M-H]^- (m/z)	Formulae	Tentative Identification	Class of compounds	Samples
2.41	289	C₁₅H₁₄O₆	Catechin	Flavanol	S
2.43	289	C₁₅H₁₄O₆	Epicatechin	Flavanol	S
2.87	387	C₂₀H₂₀O₈	Pentamethoxy hydroxy flavonol	Flavanol	S
2.88	461	C₂₁H₁₈O₁₂	Luteolin-O-glucuronide	Flavone	L
2.89	179	C₉H₈O₄	Caffeic acid	Hydroxycinnamic acid	S
3.33	165	C₉H₁₀O₃	Ethoxy benzoic acid	Hydroxybenzoic acid	L
3.33	133	C₄H₆O₅	Malic acid	Organic acid	L
4.24	147	C₉H₈O₂	Cinnamic acid	Hydroxycinnamic acid	L
4.42	207	C₁₀H₈O₅	7,8-Dihydroxy-6-methoxycoumarin	Hydroxycinnamic acid	S; L
6.55	169	C₇H₆O₅	Gallic acid	Hydroxybenzoic acid	S; L
8.4	343	C₁₅H₂₀O₉	Homovanilic acid-O-hexoside	Hydroxyphenylacetic acid	S
9.82	137	C₇H₆O₃	Salicylic acid	Hydroxybenzoic acid	L
11.63	153	C₇H₆O₄	Protocatechuic acid	Hydroxybenzoic acid	S; L
14.96	609	C₂₇H₃₀O₁₆	Kaempferol-diglucoside	Flavonol	L
15.12	609	C₂₇H₃₀O₁₆	Rutin	Flavonol	S; L
16.43	255	C₁₅H₁₂O₄	Pinocembrin	Flavanone	S
17.89	593	C₃₀H₂₆O₁₃	Tiliroside	Flavonol	L
19	447	C₂₁H₂₀O₁₁	Kaempferol-3-O-glucoside	Flavonol	S
19.46	121	C₇H₆O₂	4-hydroxybenzaldehyde	Hydroxybenzaldehyde	S
20.13	593	C₂₇H₃₀O₁₅	Kaempferol-3-O-rutinoside	Flavonol	S; L
24.82	435	C₂₁H₂₄O₁₀	Phloridzin	Dihydrochalcone	L
26.12	579	C₂₇H₃₂O₁₄	Naringin	Flavanone	S
26.65	447	C₂₁H₁₉O₁₁	Kaempferol 7- O-glucoside	Flavonol	L
26.96	447	C₂₁H₂₀O₁₁	Kaempferol-3-O-glucoside	Flavonol	L
27.03	593	C₃₀H₂₆O₁₃	Tiliroside	Flavonol	S
29.9	289	C₁₅H₁₄O₆	Catechin	Flavanol	L
29.9	289	C₁₅H₁₄O₆	Epicatechin	Flavanol	L
32.39	271	C₁₅H₁₂O₅	Naringenin	Flavanone	S
34	625	C₂₇H₃₀O₁₇	Quercetin 3-sophoroside	Flavonol	L
35.8	223	C₁₁H₁₂O₅	Sinapic acid	Hydroxycinnamic acid	S; L
39.14	595	C₂₇H₃₂0₁₅	Naringenin-O-dihexoside	Flavanone	L
43.79	463	C₂₁H₂₀O₁₂	Quercetin-3-O-glucoside	Flavonol	L
45.35	817	C₂₇H₃₀O₁₆	Kaempferol 3-diglucoside-7-glucoside	Flavonol	S; L
48.7	255	C₁₅H₁₂O₄	Isoliquiritigenin	Chalcone	S
50.05	253	C₁₅H₁₀O₄	Daidzein	Isoflavonoid	S
51.2	479	C₂₁H₂₀O₁₃	Myricetin-3-O-glucoside	Flavonol	S
51.48	283	C₁₆H₁₂O₅	Bichanin A	Isoflavonoid	S
53	285	C₁₅H₁₀O₆	Kaempferol	Flavonol	S
53.25	285	C₁₆H₁₄O₅	Vestitone	Isoflavonoid	S
53.38	329	C₁₇H₁₄O₇	Quercetin-dimethyl-ether	Flavonol	L
55.64	269	C₁₆H₁₄O₄	Medicarpin	Isoflavonoid	S; L
56.38	285	C₁₅H₁₀O₆	Kaempferol	Flavonol	L
56.64	301	C₁₅H₁₀O₇	Quercetin	Flavonol	S; L
58.8	271	C₁₆H₁₆O₄	Neovestitol	Isoflavonoid	S
58.91	271	C₁₅H₁₂O₅	Naringenin	Flavanone	L
60	255	C₁₅H₁₂O₄	Pinocembrin	Flavanone	S; L
60.2	267	C₁₆H₁₂O₄	Formononetin	Isoflavonoid	S; L
61.07	271	C₁₆H₁₆O₄	Vestitol	Isoflavonoid	S
63.09	315	C₃₃H₃₈O₂₀	Quercetin-7-methyl-ether	Flavonol	S
63.11	313	C₁₆H₁₂O₆	Luteolin 3'-methyl ether	Flavone	L
66.37	283	C₁₆H₁₂O₅	Galangin-5-methyl ether	Flavonol	L
69.87	285	C₁₇H₁₈O₄	(3S) -7-O-methylvestitol	Isoflavonoid	S
71.76	369	C₂₁H₂₁O₆	Pinobanksin-3-O-hexanonate	Flavonol	S
73.94	353	C₁₆H₁₈O₉	Chlorogenic acid	Hydroxycinnamic acid	S
76.57	435	C₂₁H₂₄O₁₀	Phloridzin	Dihydrochalcone	S

	Pair canonical
Variables	1ª Dimension	2ª Dimension
Phenols	0.98	0.21
Flavonoids	0.96	-0.27
βcarotene/linoleic acid	0.53	0.12
DPPH^a	-0.88	-0.02
r^b	0.89	0.15
F^c	15.74**	0.577^ns
α^d	0.00	0.45

Brasil

Brasil

Phytochemical study and antioxidant activity of Dalbergia ecastaphyllum

Abstract

Resumo

Introduction

Materials and Methods

Sampling

Microbiological analyses

Chemical composition

Hydro-alcoholic extract

Fatty acids

Nutritional quality index of lipid fraction

Total phenols and total flavonoids

Identification of chemical compounds by LC / MS

Antioxidant activity

Free radical scavenging activity - DPPH (1,1-diphenyl-2-picrylhydrazyl)

β-carotene bleaching assay

Statistical analyses

Results and Discussion

Microbiological analyses

Fatty acids

Total phenols and total flavonoids

Identification of chemical compounds by LC/MS

Antioxidant Activities

Conclusion

Acknowledgements

References

Edited by

Publication Dates

History