Polyphenolic Composition and Antioxidant Activity of Aqueous and Ethanolic Extracts from Uncaria tomentosa Bark and Leaves

Mirtha Navarro-Hoyos; Diego Alvarado-Corella; Ileana Moreira-Gonzalez; Elizabeth Arnaez-Serrano; Maria Monagas-Juan

doi:10.3390/antiox7050065

Navarro-Hoyos, Mirtha;Alvarado-Corella, Diego;Moreira-Gonzalez, Ileana;Arnaez-Serrano, Elizabeth;Monagas-Juan, Maria

2018-05-11 00:00:00

antioxidants Article Polyphenolic Composition and Antioxidant Activity of Aqueous and Ethanolic Extracts from Uncaria tomentosa Bark and Leaves 1 , ID 2 3 Mirtha Navarro-Hoyos * , Diego Alvarado-Corella , Ileana Moreira-Gonzalez , 3 4 Elizabeth Arnaez-Serrano and Maria Monagas-Juan Department of Chemistry, University of Costa Rica (UCR), Sede Rodrigo Facio, San Pedro de Montes de Oca, San José 2060, Costa Rica Department of Biology, University of Costa Rica (UCR), Sede Rodrigo Facio, San Pedro de Montes de Oca, San Jose 2060, Costa Rica; luis.alvaradocorella@ucr.ac.cr Department of Biology, Technological University of Costa Rica (TEC), Cartago 7050, Costa Rica; imoreira@itcr.ac.cr (I.M.-G.), earnaez@itcr.ac.cr (E.A.-S.) Institute of Food Science Research (CIAL), Spanish National Research Council (CSIC), C/Nicolás Cabrera 9, 28049 Madrid, Spain; mjm@usp.org * Correspondence: mnavarro@codeti.org; Tel.: +506-8873-5539 Received: 24 March 2018; Accepted: 2 May 2018; Published: 11 May 2018 Abstract: Uncaria tomentosa constitutes an important source of secondary metabolites with diverse biological activities mainly attributed until recently to alkaloids and triterpenes. We have previously reported for the ﬁrst-time the polyphenolic proﬁle of extracts from U. tomentosa, using a multi-step process involving organic solvents, as well as their antioxidant capacity, antimicrobial activity on aerial bacteria, and cytotoxicity on cancer cell lines. These promising results prompted the present study using food grade solvents suitable for the elaboration of commercial extracts. We report a detailed study on the polyphenolic composition of aqueous and ethanolic extracts of U. tomentosa bark and leaves (n = 16), using High Performance Liquid Chromatography coupled with Mass Spectrometry (HPLC-DAD/TQ-ESI-MS). A total of 32 compounds were identiﬁed, including hydroxybenzoic and hydroxycinnamic acids, ﬂavan-3-ols monomers, procyanidin dimers and trimers, ﬂavalignans–cinchonains and propelargonidin dimers. Our ﬁndings showed that the leaves were the richest source of total phenolics and proanthocyanidins, in particular propelargonidin dimers. Two-way Analysis of Variance (ANOVA) indicated that the contents of procyanidin and propelargonidin dimers were signiﬁcantly different (p < 0.05) in function of the plant part, and leaves extracts showed higher contents. Oxygen Radical Absorbance Capacity (ORAC) and 2,2-diphenyl-1-picrylhidrazyl (DPPH) values indicated higher antioxidant capacity for the leaves (p < 0.05). Further, correlation between both methods and procyanidin dimers was found, particularly between ORAC and propelargonidin dimers. Finally, Principal Component Analysis (PCA) analysis results clearly indicated that the leaves are the richest plant part in proanthocyanidins and a very homogenous material, regardless of their origin. Therefore, our ﬁndings revealed that both ethanol and water extraction processes are adequate for the elaboration of potential commercial extracts from U. tomentosa leaves rich in proanthocyanidins and exhibiting high antioxidant activity. Keywords: U. tomentosa; UPLC-DAD; TQ-ESI/MS; polyphenols; proanthocyanidins; propelargonidins; procyanidins; mass spectrometry; antioxidant Antioxidants 2018, 7, 65; doi:10.3390/antiox7050065 www.mdpi.com/journal/antioxidants Antioxidants 2018, 7, 65 2 of 18 1. Introduction Uncaria tomentosa L., commonly known as cat’s claw, is a creeper vine typical of the rainy tropical forest that belongs to the Rubiaceae family. It is naturally distributed in South America, mainly in Peru and Brazil as well as in Central America, and it is traditionally used as a medicinal plant. Around 50 compounds have been isolated from U. tomentosa, from which approximately 35 chemical markers can be considered exclusive to this species, including triterpenes [1], alkaloids [2] and polyphenols [3]. The special interest on this plant is due to the fact that numerous scientiﬁc studies report a wide variety of biological activities [4], such as immunomodulatory properties [3], as well as their antioxidant, anti-inﬂammatory and cardiovascular effects and protective properties against cancer, among others [5]. Although originally attributed to alkaloids, recent studies suggest that the health effects derived from U. tomentosa could be attributed to a synergistic interaction among different chemical compounds present in this plant [6]. Of particular interest are polyphenols, for which there is strong evidence of having multiple molecular targets, modulating pro-inﬂammatory gene expression, interacting with phospholipid membranes [7] and modulating pathways related to chronic inﬂammation and energy metabolism [8]. Regarding polyphenols, U. tomentosa studies are scarce and mainly focused on a particular subclass, for instance on hydroxycinnamic acids [9,10], ﬂavonols [11], ﬂavan-3-ols [12,13] and cinchonains [14]. Recently, a detailed characterization of U. tomentosa leaves, bark, stem and wood has been reported indicating a high ﬂavan-3-ol content, particularly in procyanidin dimers and trimers, propelargonidin dimers and cinchonain-type ﬂavalignans [15] in leaves and bark. Also, assessment of biological activities of U. tomentosa proanthocyanidins showed evidence on the relationship between proanthocyanidin contents and antioxidant capacity, antimicrobial effect against Staphylococcus aureus, Enterococcus faecalis and Pseudomonas aeruginosa respiratory pathogens [16], and in vitro cytotoxicity, with high selectivity for AGS gastric and SW620 colon adenocarcinoma cell lines, mainly attributed to the content of propelargonidin dimers [17]. These promising results about the bioactivity of U. tomentosa proanthocyanidin extracts and their potential health effects were subject of an industrial patent [18] and prompted the need to further explore the viability of elaborating polyphenolic extracts form U. tomentosa using food-grade solvents (i.e., aqueous or ethanolic extracts) with potential use as Dietary Supplements. Previous studies carried out with U. tomentosa aqueous and ethanolic extracts indicated antioxidant activity in vitro [2,19,20] and other biological activities such as important effects on mono- nuclear blood cells [21] with 95% ethanol extracts; however, detailed characterization of the extracts was not performed. Our present study focuses on the detailed phenolic characterization by HPLC-DAD/TQ-ESI-MS of aqueous and ethanolic extracts from both bark and leaves (n = 16) of U. tomentosa cultivated in Costa Rica, as well as to determine their antioxidant activity by Oxygen Radical Absorbance Capacity (ORAC) and 2,2-diphenyl-1-picrylhidrazyl (DPPH) methods. Finally, statistical analyses to determine the inﬂuence of factors, such as plant part and solvents, on the polyphenolic composition of U. tomentosa extracts were explored. 2. Results and Discussion 2.1. Phenolic Yield and Total Phenolic Content in U. tomentosa Extracts The aqueous and ethanolic extraction methods described in Section 3, allowed to obtain extracts with yields as shown in Table 1. Considering the plant part, leaves exhibited the highest yields independently of the plant location with an overall average of 5.26%, whereas barks showed much lower yields with 2.28% average. For both parts, barks and leaves, ethanolic extraction yields were slightly higher (average: 2.54% and 5.88%, respectively) than those of aqueous extracts (average: 2.01% and 4.64%, respectively). In regards to total polyphenols (TP), leaves showed higher contents than barks and considering the geographical location, U. tomentosa leaves from Los Chiles showed the Antioxidants 2018, 7, 65 3 of 18 highest TP values in both aqueous and ethanolic solvents (385.6 and 387.6 mg gallic acid equivalents (GAE)/g extract respectively), followed by Asomat (335.0 and 362.4 mg GAE/g extract), whereas Sarapiqui showed the lowest values (218.2 and 321.0 mg GAE/g extract). In the case of barks, Asomat and Sarapiqui ethanolic extracts showed the highest TP values (295.2 and 321.0 mg GAE/g extract, respectively). Similar trends were observed for the ﬂavan-3-ols (PRO) content. Table 1. Extraction yield, total phenolic (TP) and ﬂavan-3-ols (PRO) for aqueous and ethanolic extracts from U. tomentosa. 1 2 3 Samples Extraction Yield (%) TP (mg/g) PRO (mg/g) Aqueous Extracts Leaves Asomat (AS) 4.95 335.2 6.6 255.6 6.5 Los Chiles (LC) 4.22 385.6 1.1 304.9 4.0 Palacios (PA) 3.95 311.0 0.4 201.9 2.6 Sarapiqui (SR) 5.45 218.2 5.3 152.2 2.9 Bark Asomat (AS) 1.93 236.0 5.8 166.4 2.3 Los Chiles (LC) 1.74 177.5 1.6 108.4 3.4 Palacios (PA) 1.71 138.2 4.5 69.8 1.9 Sarapiqui (SR) 2.65 201.5 3.5 114.6 2.2 Ethanolic extracts Leaves Asomat (AS) 5.99 362.4 5.5 300.5 6.0 Los Chiles (LC) 5.39 387.6 3.0 298.6 8.4 Palacios (PA) 6.12 340.4 3.7 260.3 3.7 Sarapiqui (SR) 6.03 342.1 2.8 281.5 4.8 Bark Asomat (AS) 2.88 295.2 3.1 198.3 4.5 Los Chiles (LC) 1.26 196.2 4.5 88.2 3.3 Palacios (PA) 3.17 279.8 6.2 194.8 5.5 Sarapiqui (SR) 2.86 321.0 3.6 216.7 5.3 1 2 3 g of extract/g of dry material expressed as %; mg of gallic acid equivalent/g extract; mg cyanidin chloride equivalents/g extract. In order to assess the inﬂuence of plant part and extraction solvent on TP and PRO content, a two-way Analysis of Variance (ANOVA) was carried out. Results showed signiﬁcant differences (p < 0.05) for both factors, plant part and solvent used, with ethanolic procedure yielding better TP and PRO values for both plant parts. In addition, importantly, ﬁndings indicated leaves extracts are richer in both contents than their bark counterparts, which is in agreement with a recent study on U. tomentosa phenolic extracts obtained through an extraction and puriﬁcation method using different organic solvents [15]. 2.2. UPLC-DAD/TQ-ESI-MS Analysis of U. tomentosa Polyphenolic Extracts The UPLC-DAD/TQ-ESI-MS analysis was performed in the 16 aqueous and ethanolic extracts from U. tomentosa, as described in Section 3. Determination of 32 phenolic compounds was achieved, comprising non-ﬂavonoid polyphenols, including seven hydroxybenzoic acids, namely benzoic, 4-hydroxybenzoic, salicylic, gallic, protocatechuic, syringic and vanillic acids; and four hydroxycinnamic acids, namely caffeic, p-coumaric, ferulic and isoferulic acids. Among ﬂavonoid polyphenols, both ﬂavan-3-ols monomers [(+)-catechin and ()-epicatechin] were found, as well as Antioxidants 2018, 7, 65 4 of 18 eight procyanidin dimers, three procyanidin trimers, and four propelargonidin dimers. Also, four ﬂavalignans-cinchonains were identiﬁed (Tables 2 and 3). Multiple reaction monitoring (MRM) transitions under set tandem mass spectrometry (MS/MS) parameters were recorded for compounds found in extracts from U. tomentosa bark and leaves. For instance, at m/z 289/245 for ﬂavan-3-ols monomers [(+)-catechin and ()-epicatechin], at m/z 577/289 for procyanidin dimers, at m/z 561/289 for propelargonidin dimers, at m/z 865/577 Antioxidants 2018, 7, x FOR PEER REVIEW 4 of 17 for procyanidin trimers and at m/z 451/341 for ﬂavalignans-cinchonains. As shown in Figure S1 (Supplementary Materials), MS/MS allowed to identify the different procyanidin dimers and Materials), MS/MS allowed to identify the different procyanidin dimers and propelargonidin dimers. propelargonidin dimers. These results constitute the ﬁrst report, to our knowledge, of propelargonidins These results constitute the first report, to our knowledge, of propelargonidins presence in presence in U. tomentosa ethanolic and aqueous extracts. U. tomentosa ethanolic and aqueous extracts. In agreement with the TP and PRO determinations, the UPLC analysis revealed that In agreement with the TP and PRO determinations, the UPLC analysis revealed that the leaves the leaves have higher phenolic content (17,482.3–32,323.3 g/g of extract) than the barks have higher phenolic content (17,482.3–32,323.3 µg/g of extract) than the barks (5122.0–17,770.2 µg/g (5122.0–17,770.2 g/g of extract). Differences in the distribution of phenolic compounds also of extract). Differences in the distribution of phenolic compounds also occur. For example, in the case occur. For example, in the case of ﬂavan-3-ols (Figure 1) propelargonidin dimer (Rt = 4.43 min) of flavan-3-ols (Figure 1) propelargonidin dimer (Rt = 4.43 min) (3067.8–4978.9 µg/g extract), (3067.8–4978.9 g/g extract), propelargonidin dimer (Rt = 5.65 min) (2177.2–5209.1 g/g extract) and propelargonidin dimer (Rt = 5.65 min) (2177.2–5209.1 µg/g extract) and procyanidin B4 (1771.8–3931.9 procyanidin B4 (1771.8–3931.9 g/g extract) are the most abundant ﬂavan-3-ols in leaves, whereas µg/g extract) are the most abundant flavan-3-ols in leaves, whereas in barks, procyanidin B2 in barks, procyanidin B2 (378.5–4011.4 g/g extract) and ()-epicatechin (712.6–3827.0 g/g extract) (378.5–4011.4 µg/g extract) and (−)-epicatechin (712.6–3827.0 µg/g extract) appear to be more appear to be more abundant. This latter ﬂavan-3-ol monomer is found in larger concentration than abundant. This latter flavan-3-ol monomer is found in larger concentration than (+)-catechin (+)-catechin (66.4–1592.5 g/g extract) in all leaves and bark samples. (66.4–1592.5 µg/g extract) in all leaves and bark samples. Figure 1. Procyanidin (PC), propelargonidin (PP) and flavalignans (FL) general chemical structures. Figure 1. Procyanidin (PC), propelargonidin (PP) and ﬂavalignans (FL) general chemical structures. When considering subclasses of polyphenols (Figure 2), barks show variable contents, with When considering subclasses of polyphenols (Figure 2), barks show variable contents, with procyanidin dimers as the most abundant group in Los Chiles (7971.4 µg/g of extract) aqueous procyanidin dimers as the most abundant group in Los Chiles (7971.4 g/g of extract) aqueous extract, extract, followed by Sarapiqui (6085.3–6464.1 µg/g of extract) in ethanolic and aqueous extracts, followed by Sarapiqui (6085.3–6464.1 g/g of extract) in ethanolic and aqueous extracts, respectively. respectively. Los Chiles and Sarapiqui aqueous extracts exhibited the highest content of flavan-3-ols Los Chiles and Sarapiqui aqueous extracts exhibited the highest content of ﬂavan-3-ols monomers monomers (3994.4 and 4382.8 µg/g of extract, respectively), while hydroxybenzoic acids (HBA) is the (3994.4 and 4382.8 g/g of extract, respectively), while hydroxybenzoic acids (HBA) is the third more third more abundant group, with the highest HBA contents in Los Chiles (6206.28 µg/g of extract) abundant group, with the highest HBA contents in Los Chiles (6206.28 g/g of extract) followed by followed by Palacios (2772.6 µg/g of extract), both in ethanolic samples. Palacios (2772.6 g/g of extract), both in ethanolic samples. In contrast, extracts from leaves showed a more uniform subclass distribution, for instance, all In contrast, extracts from leaves showed a more uniform subclass distribution, for instance, all extracts are particularly rich in propelargonidin dimers (7904.3–14,390.8 µg/g of extract), followed by extracts are particularly rich in propelargonidin dimers (7904.3–14,390.8 g/g of extract), followed by procyanidin dimers (3593.1–9988.8 µg/g of extract) and flavalignans-cinchonains (1074.6–7058.0 µg/g procyanidin dimers (3593.1–9988.8 g/g of extract) and ﬂavalignans-cinchonains (1074.6–7058.0 g/g of extract). of extract). Antioxidants 2018, 7, 65 5 of 18 Table 2. Phenolic composition of aqueous extracts from bark and leaves of U. tomentosa. Leaves Extracts Bark Extracts Compound AS LC PA SR AS LC PA SR Concentration (g/g Extract) Hydroxybenzoic acids Benzoic acid 71.2 6.9 50.3 0.8 225.8 7.6 120.0 9.8 343.0 23.2 60.3 5.8 1181.6 89.0 13.0 0.5 Salicylic acid 27.7 2.3 22.9 0.4 24.7 1.1 29.0 1.9 20.1 1.8 56.4 0.9 105 6.9 197.6 1.4 4-hydroxybenzoic acid 35.2 1.1 143.6 3.2 200.0 4.7 41.1 1.1 113.7 7.7 22.7 1.1 164.7 6.6 37.6 1.9 Protocatechuic acid 60.5 1.4 323.0 5.5 495.5 13.2 120.5 6.9 983.8 61.6 292.2 9.6 696.5 52.3 808.0 18.7 Gallic acid 47.4 1.2 188.5 5.7 19.5 1.4 10.7 0.9 42.6 3.3 25.3 1.3 27.9 2.9 28.3 0.4 Vainillinic acid 5.8 0.1 9.5 0.9 10.7 0.3 4.8 0.1 94.8 6.6 84.8 8.3 136.7 7.5 45.2 2.3 Syringic acid 3.4 0.0 6.9 0.1 6.8 0.1 4.4 0.2 20.5 1.0 26.8 1.5 21.9 0.5 12.7 0.1 Hydroxybenzoic acids 251.3 744.8 983.0 330.3 1618.5 568.5 2334.3 1142.5 Hydroxycinnamic acids p-cumaric acid 11.2 1.1 42.9 3.2 18.1 4.7 37.5 1.1 5.5 7.7 5.2 1.1 8.6 6.6 2.2 1.9 Caffeic acid 13.9 0.7 91.4 1.4 38.4 0.9 15.3 0.5 12.7 0.6 15.9 1.4 14.4 1.3 7.3 0.6 Ferulic acid 22.2 0.7 46.1 3.3 59.4 2.0 31.2 1.6 22.7 1.1 12.2 0.6 11.0 0.5 14.3 1.0 Isoferulic acid 15.4 0.2 7.8 0.7 12.0 0.3 10.9 1.0 nd nd nd nd Hydroxycinnamic acids 62.7 188.3 128.0 94.9 40.9 33.2 34.1 23.8 Flavan-3-ols: monomers (+)-Catechin 1170.3 30.5 947.2 39.7 1181.0 11.7 1592.5 32.2 112.4 2.8 691.5 24.8 185.3 18.4 555.8 26.2 ()-Epicatechin 3346.5 46.6 1901.7 39.6 2179.4 68.8 2954.5 73.0 835.1 27.8 3302.9 194.2 1032.9 19.3 3827.0 76.6 å Monomers 4516.8 2848.8 3360.4 4547.0 947.4 3994.4 1218.3 4382.8 Flavan-3-ols: procyanidin dimers Procyanidin B1 1233.6 39.0 1536.6 16.0 829.4 16.3 887.1 19.6 68.2 1.8 587.2 25.5 105.4 10.8 327.4 10.1 Procyanidin B2 2415.6 35.6 1651.0 26.9 1085.5 24.9 1291.9 29.8 1085.3 20.8 4011.4 297.6 1061.2 78.3 3777.0 68.0 Procyanidin B3 1119.1 32.0 2417.8 34.3 893.1 36.3 1383.2 32.7 53.2 1.7 350.3 17.5 70.2 2.3 158.8 9.5 Procyanidin B4 3642.9 96.5 3888.7 79.0 1886.0 57.9 2979.5 68.7 479.8 5.5 2720.8 159.0 681.5 48.6 1715.3 5.2 Procyanidin B5 317.1 4.0 159.5 7.4 137.6 8.2 191.0 7.3 72.6 2.7 301.8 18.9 50.4 3.6 448.3 12.2 Procyanidin B7 158.8 12.2 164.2 10.1 47.3 2.7 118.4 2.1 nd nd nd nd Procyanidin B (5.47 min) 154.8 11.0 171.0 12.9 63.2 1.1 116.5 6.7 nd nd nd nd Procyanidin B (9.27 min) 68.1 2.4 nd 20.2 1.4 79.0 6.4 nd nd nd 37.3 1.2 Procyanidin dimers 9110.0 9988.8 4962.2 7046.6 1759.0 7971.4 1968.7 6464.1 å Antioxidants 2018, 7, 65 6 of 18 Table 2. Cont. Leaves Extracts Bark Extracts Compound AS LC PA SR AS LC PA SR Concentration (g/g Extract) Flavan-3-ols: propelargonidin dimers Propelargonidin dimer 4978.9 161.5 4125.9 84.3 4689.4 185.5 4477.4 235.3 22.3 1.6 126.2 6.6 46.8 2.7 115.3 2.1 (4.43 min) Propelargonidin dimer 3369.6 102.6 2661.0 39.5 3179.5 23.3 2981.4 52.4 118.3 4.1 346.7 15.7 94.2 9.0 257.0 4.7 (5.01 min) Propelargonidin dimer 5209.1 59.9 2602.3 23.3 2935.9 60.4 2748.8 69.6 238.5 5.8 1135.2 71.3 213.2 19.7 1153.2 13.6 (5.65 min) Propelargonidin dimer 833.2 5.1 352.8 2.8 298.9 24.8 339.6 3.1 17.6 1.0 56.8 2.7 9.2 0.9 83.2 4.5 (9.27 min) å Propelargonidin dimers 14,390.8 9742.1 11,103.7 10,547.3 396.6 1664.9 363.3 1608.7 Flavan-3-ols: procyanidin trimers Trimer T2 nd 104.6 11.3 nd nd nd 235.1 25.2 nd nd Procyanidin C1 303.7 9.0 190.7 6.3 64.3 0.6 106.3 3.9 480.8 45.4 2006.3 169.3 323.2 2.1 2148.3 70.4 Trimer B (5.78 min) 176.6 13.9 395.7 15.4 101.3 6.7 145.1 8.5 86.6 3.8 473.6 16.9 54.5 3.8 585.0 13.9 Procyanidin trimers 480.3 691.0 165.6 251.4 567.4 2715.1 377.7 2733.4 Flavalignans Cinchonain (7.37 min) 937.8 21.5 325.4 18.0 258.3 11.3 354.8 25.8 183.4 6.9 391.8 8.6 107.2 4.2 213.1 10.4 Cinchonain (9.05 min) 786.9 9.8 420.4 5.3 249.6 20.9 522.8 19.8 18.9 1.1 49.5 2.8 22.5 1.2 15.3 0.3 Cinchonain (9.30 min) 977.6 20.8 565.4 17.4 335.5 16.7 570.8 20.2 24.7 0.6 55.7 2.6 24.0 1.2 21.4 1.1 Cinchonain (12.27 min) 809.3 11.3 301.3 7.4 231.2 11.9 337.9 19.1 189.3 2.6 325.7 11.9 115.6 9.3 207.9 7.3 Flavalignans 3511.6 1612.4 1074.6 1786.3 416.3 822.7 269.4 457.7 AS—Asomat; LC—Los Chiles; PA—Palacios; SR—Sarapiquí; nd—not detected. Table 3. Phenolic composition of ethanolic extracts from bark and leaves of U. tomentosa. Leaves Extracts Bark Extracts Compound AS LC PA SR AS LC PA SR Concentration (g/g Extract) Hydroxybenzoic acids Benzoic acid 46.3 0.2 88.9 9.8 165.9 8.8 64.8 4.3 1053.4 41.9 5102.6 69.5 1567.6 22.0 20.1 1.4 Antioxidants 2018, 7, 65 7 of 18 Table 3. Cont. Leaves Extracts Bark Extracts Compound AS LC PA SR AS LC PA SR Concentration (g/g Extract) Salicylic acid 12.0 1.1 10.0 0.5 12.4 0.6 12.0 0.6 27.6 0.5 175.4 2.3 100.8 7.1 110.0 3.3 4-hydroxybenzoic acid 19.9 0.7 23.2 1.3 124.3 4.4 26.2 1.4 203.0 6.2 117.2 4.6 176.2 15.3 42.2 2.2 Protocatechuic acid 25.7 1.8 61.4 1.0 118.4 3.3 48.5 2.8 932.9 21.5 283.8 4.3 742.1 61.7 326.5 9.2 Gallic acid 5.8 0.3 10.5 0.1 11.5 0.6 2.8 0.1 28.1 1.7 32.5 1.1 15.8 1.1 15.4 0.2 Vainillinic acid 3.5 0.0 5.8 0.2 12.6 0.6 4.4 0.1 150.3 6.6 412.1 16.7 147.7 10.5 47.0 1.8 Syringic acid nd 3.4 0.3 5.3 0.2 nd 40.9 2.1 82.7 3.0 22.4 1.3 12.5 0.1 Hydroxybenzoic acids 113.2 203.2 450.4 158.6 2436.1 6206.3 2772.6 573.8 Hydroxycinnamic acids p-cumaric acid 4.6 0.7 8.1 1.3 22.5 4.4 22.1 1.4 9.9 6.2 7.6 4.6 4.8 15.3 2.6 2.2 Caffeic acid 5.3 0.5 7.5 0.3 7.4 0.4 5.4 0.3 9.0 0.6 7.5 0.7 10.8 1.0 4.5 0.2 Ferulic acid 10.2 1.0 17.9 0.9 30.1 1.9 16.7 1.5 31.5 1.1 32.4 3.2 11.8 0.9 21.7 0.8 Isoferulic acid 14.4 0.1 nd 7.7 0.2 nd 21.0 1.5 38.9 4.0 nd nd Hydroxycinnamic acids 34.5 33.6 67.7 44.3 71.3 86.4 27.4 28.8 Flavan-3-ols: monomers (+)-Catechin 615.1 6.7 674.2 16.0 412.0 14.1 1173.2 33.4 66.4 5.5 67.7 4.7 100.7 8.4 181.1 11.3 ()-Epicatechin 2163.7 62.3 1554.3 52.9 1097.2 31.8 2159.0 45.3 712.6 44.0 978.3 38.9 1444.3 142.2 3148.6 64.9 å Monomers 2778.8 2228.5 1509.2 3332.2 779.0 1046.0 1545.0 3329.6 Flavan-3-ols: procyanidin dimers Procyanidin B1 621.5 13.4 1114.6 40.6 313.6 8.4 769.6 27.9 23.2 0.9 21.8 1.5 99.0 8.2 170.5 5.8 Procyanidin B2 1363.7 35.7 1399.3 24.3 539.1 18.2 992.1 36.8 527.4 19.8 378.5 20.2 1592.3 55.9 2792.9 83.7 Procyanidin B3 830.0 26.6 2353.2 16.1 687.6 11.4 1708.5 93.7 19.2 1.0 14.2 0.2 69.3 1.6 68.3 3.4 Procyanidin B4 2476.6 41.9 3931.9 108.9 1711.8 13.6 3172.6 73.6 370.9 15.7 319.1 17.0 1866.0 86.1 2015.7 10.4 Procyanidin B5 291.0 6.4 268.7 8.3 122.6 9.9 217.2 3.4 72.9 2.8 53.9 0.1 292.0 5.6 744.6 13.6 Procyanidin B7 161.4 9.3 267.6 6.1 85.5 4.8 170.5 14.5 nd nd nd 112.2 5.5 Procyanidin B (5.47 min) 137.8 9.6 263.3 7.5 96.0 10.6 184.3 13.2 nd nd 65.1 4.3 123.1 9.4 Procyanidin B (9.27 min) 53.4 2.2 nd 36.8 2.8 76.0 9.4 nd nd nd 58.0 3.3 Procyanidin dimers 5935.4 9598.5 3593.1 7290.8 1013.6 787.4 3983.8 6085.3 Flavan-3-ols: propelargonidin dimers Propelargonidin dimer 3239.3 63.1 3067.8 72.3 3644.5 59.8 4660.6 105.0 9.9 1.0 22.0 0.8 16.4 2.4 68.7 5.7 (4.43 min) Propelargonidin dimer 2503.6 26.9 2179.3 22.1 2926.1 37.8 3343.7 57.1 85.7 6.0 58.0 5.1 153.6 6.4 231.7 18.0 (5.01 min) Antioxidants 2018, 7, 65 8 of 18 Table 3. Cont. Leaves Extracts Bark Extracts Compound AS LC PA SR AS LC PA SR Concentration (g/g Extract) Propelargonidin dimer 3253.4 12.5 2177.2 33.1 2178.4 82.6 2480.8 38.0 112.8 4.3 77.6 2.4 308.0 13.8 895.5 24.3 (5.65 min) Propelargonidin dimer 795.7 30.3 480.0 15.5 471.1 20.5 576.8 21.0 12.2 1.2 12.4 0.8 42.3 1.3 143.8 5.7 (9.27 min) Propelargonidin dimers 9792.0 7904.3 9220.2 11,061.9 220.6 169.9 520.2 1339.7 Flavan-3-ols: procyanidin trimers Trimer T2 nd nd nd nd nd nd nd nd Procyanidin C1 243.4 25.4 260.6 13.2 69.7 0.4 181.2 9.1 37.8 0.4 nd 744.6 10.8 1636.2 76.2 Trimer B (5.78 min) nd nd nd nd nd nd nd nd Procyanidin trimers 243.4 260.6 69.7 181.2 37.8 0.0 744.6 1636.2 Flavalignans Cinchonain (7.37 min) 1723.6 23.5 1011.9 17.8 567.2 14.4 773.0 33.1 236.0 15.1 170.7 9.8 745.7 20.4 447.7 2.5 Cinchonain (9.05 min) 2010.3 17.0 1816.3 48.4 744.3 23.4 1544.1 77.1 19.7 1.2 20.7 2.6 63.8 5.1 28.4 1.4 Cinchonain (9.30 min) 1795.3 31.1 1901.5 32.5 773.9 23.1 1358.0 65.7 22.7 2.0 25.8 0.9 56.0 2.5 34.6 1.9 Cinchonain (12.27 min) 1528.8 20.7 900.5 14.5 486.7 16.2 727.2 23.3 285.3 10.1 217.3 12.9 710.2 25.7 471.9 17.3 Flavalignans 7058.0 5630.1 2572.0 4402.1 563.7 434.4 1575.7 982.6 AS—Asomat; LC—Los Chiles; PA—Palacios; SR—Sarapiquí; nd—not detected. Antioxidants 2018, 7, x FOR PEER REVIEW 8 of 17 Antioxidants 2018, 7, 65 9 of 18 35,000 Hydroxybenzoic acids 30,000 Hydroxycinnamic acids 25,000 Flavan-3-ol Monomers 20,000 Procyanidin dimers 15,000 Propelargonidin dimers 10,000 Procyanidin trimers 5,000 Flavalignans-Cinchonains Figure 2. Quantiﬁcation of polyphenols subclasses by Ultra Performance Liquid Chromatography Figure 2. Quantification of polyphenols subclasses by Ultra Performance Liquid Chromatography coupled with Mass Spectrometry (UPLC-DAD/TQ-ESI-MS) for aqueous and ethanolic extracts of coupled with Mass Spectrometry (UPLC-DAD/TQ-ESI-MS) for aqueous and ethanolic extracts of U. tomentosa leaves (L) and barks (B). Solvent: Aq—aqueous, Et—ethanolic; Origin: AS—Asomat; U. tomentosa leaves (L) and barks (B). Solvent: Aq—aqueous, Et—ethanolic; Origin: AS—Asomat; LC—Los Chiles; PA—Palacios; SR—Sarapiqui. LC—Los Chiles; PA—Palacios; SR—Sarapiqui. In order to identify the inﬂuence of plant part and extraction procedure on phenolic content In order to identify the influence of plant part and extraction procedure on phenolic content and and distribution, a two-way ANOVA was performed in the 16 extracts. This analysis showed distribution, a two-way ANOVA was performed in the 16 extracts. This analysis showed significant signiﬁcant differences (p < 0.05) in the content of ﬂavalignans-cinchonains in function of both factors, differences (p < 0.05) in the content of flavalignans-cinchonains in function of both factors, plant part plant part and solvent, with leaves and ethanol rendering the highest results. On the other hand, and solvent, with leaves and ethanol rendering the highest results. On the other hand, flavan-3-ols ﬂavan-3-ols monomers, procyanidin trimers and hydroxycinnamic acids contents were not inﬂuenced monomers, procyanidin trimers and hydroxycinnamic acids contents were not influenced by neither by neither factor, plant parts or solvent. In contrast, hydroxybenzoic acids, procyanidin dimers and factor, plant parts or solvent. In contrast, hydroxybenzoic acids, procyanidin dimers and propelargonidin dimers showed signiﬁcant differences (p < 0.05) only when considering U. tomentosa propelargonidin dimers showed significant differences (p < 0.05) only when considering U. tomentosa part material, with hydroxybenzoic acids being more abundant in barks, while procyanidin and part material, with hydroxybenzoic acids being more abundant in barks, while procyanidin and propelargonidin dimers being predominant in leaves. A similar trend was observed when comparing propelargonidin dimers being predominant in leaves. A similar trend was observed when comparing these results with previous ﬁndings reported in a detailed study on U. tomentosa phenolic extracts these results with previous findings reported in a detailed study on U. tomentosa phenolic extracts obtained through extraction and puriﬁcation with organic solvents [15], which reported a higher obtained through extraction and purification with organic solvents [15], which reported a higher presence of hydroxybenzoic acids in barks and a higher propelargonidin dimers content in leaves. presence of hydroxybenzoic acids in barks and a higher propelargonidin dimers content in leaves. In sum, our study shows that independently of the plant origin, leaves extracts exhibit high In sum, our study shows that independently of the plant origin, leaves extracts exhibit high contents of phenolic compounds and more importantly high contents of proanthocyanidins derivatives, contents of phenolic compounds and more importantly high contents of proanthocyanidins mainly propelargonidin dimers and procyanidin dimers. These compounds are linked to diverse derivatives, mainly propelargonidin dimers and procyanidin dimers. These compounds are linked bioactivities, for instance due to their antioxidant capacity, as shown in reports for commercial dietary to diverse bioactivities, for instance due to their antioxidant capacity, as shown in reports for products from grape [22] and cocoa [23], which suggest these U. tomentosa extracts’ potential for commercial dietary products from grape [22] and cocoa [23], which suggest these U. tomentosa further studies. extracts’ potential for further studies. 2.3. Evaluation of Antioxidant Capacity of U. tomentosa Polyphenolic Extracts 2.3. Evaluation of Antioxidant Capacity of U. tomentosa Polyphenolic Extracts Evaluation of the antioxidant capacity of the 16 samples was performed through Oxygen Radical Evaluation of the antioxidant capacity of the 16 samples was performed through Oxygen Radical Absorbance Capacity (ORAC) and DPPH methods (Table 4). Absorbance Capacity (ORAC) and DPPH methods (Table 4). Quantitation by UPLC (µg/ g extract) Antioxidants 2018, 7, 65 10 of 18 Table 4. Oxygen Radical Absorbance Capacity (ORAC) and 2,2-diphenyl-1-picrylhidrazyl (DPPH) antioxidant activity of aqueous and ethanolic extracts from bark and leaves of U. tomentosa. DPPH IC (g/mL) ORAC (mol TE/mg) Extraction Leaves Bark Leaves Bark Aqueous AS 12.06 0.36 5.22 0.10 5.23 0.02 8.83 0.21 LC 10.53 0.43 5.27 0.15 5.81 0.01 6.66 0.15 PA 9.65 0.44 4.07 0.15 7.84 0.03 8.98 0.06 SR 6.66 0.13 6.22 0.28 10.13 0.15 7.31 0.16 Ethanolic AS 9.48 0.40 4.47 0.15 5.95 0.05 7.88 0.18 LC 11.57 0.33 3.48 0.13 5.56 0.10 11.52 0.05 PA 8.01 0.28 6.65 0.26 9.05 0.23 7.47 0.17 SR 11.27 0.51 7.23 0.19 5.98 0.03 6.34 0.07 mol Trolox equivalents/mg extract. Origin: AS—Asomat, LC—Los Chiles, PA—Palacios, SR—Sarapiqui. Among leaves, Asomat (12.06 mol Trolox equivalents (TE)/mg extract) aqueous extract showed the highest antioxidant activity in ORAC methodology, followed by Los Chiles (11.57 mol TE/mg extract) ethanolic extract, while the lowest value was obtained for Sarapiqui (6.66 mol TE/mg extract) aqueous extract. In the case of bark samples, Sarapiqui (7.23 mol TE/mg extract) ethanolic extract showed the highest values followed by Palacios (6.65 mol TE/mg extract) in the same conditions, while the lowest value was found for Los Chiles (3.48 mol TE/mg extract) aqueous extract. DPPH values for leaves followed the same trend as ORAC results, showing that Asomat aqueous extract yielded the highest value (IC = 5.23 g/mL) followed by Los Chiles ethanolic extract (IC = 5.56 g/mL), while Sarapiqui aqueous extract showed the lowest value (IC = 10.13 g/mL). 50 50 Referring to bark samples, DPPH values also followed a similar trend as ORAC results, with Sarapiquí ethanolic extract yielding the highest antioxidant value (IC = 6.34 g/mL) and Los Chiles ethanolic extract showing the lowest antioxidant result (IC = 11.52 g/mL). These values are slightly better than previous DPPH reported results [2,24] for U. tomentosa extracts. To evaluate the inﬂuence of both factors, plant part and extraction solvent on ORAC and DPPH, a two-way ANOVA analysis was performed for both methods. Results indicated no signiﬁcant differences for DPPH. However, ORAC antioxidant capacity was inﬂuenced by U. tomentosa plant part (p < 0.05), with leaves materials rendering better results when compared to bark samples. Considering the extraction solvent, ethanolic extracts provided slightly better results than aqueous extracts but these results were not signiﬁcantly different. Literature reports on U. tomentosa bark and leaves extracts using aqueous and organic solvents show variable results, depending upon radical scavenging methods used, for instance some indicating better results for leaves [21] and ethanolic extraction [19] in agreement with our results. Our ﬁndings indicate both solvents yield interesting polyphenolic composition and antioxidant values, thus studies could be carried out using hydro-alcoholic mixtures to explore if results and processes could be further optimized for industrial application. A correlation analysis was performed between both antioxidant methods and extracts phenolic contents. Results show a positive correlation between ORAC values and total phenolics determined by UPLC (r = 0.809, p < 0.05) and by the Folin–Ciocalteau method (r = 0.883, p < 0.05). Similarly, a positive correlation was found with the PRO method (r = 0.822, p < 0.05). These results are in agreement with other reports that indicate correlation between total polyphenolic content and ORAC values for several plants [25,26]. Further, Figure 3 shows the correlation analysis performed for proanthocyanidin subclasses, including total ﬂavan-3-ols, procyanidin monomers, procyanidin dimers, propelargonidin dimers, and ﬂavalignans-cinchonains. It should be noted the signiﬁcant positive correlation with total ﬂavan-3-ols (r = 0.846, p < 0.05) (Figure 3A), procyanidin dimers (r = 0.766, p < 0.05) (Figure 3B), Antioxidants 2018, 7, 65 11 of 18 Antioxidants 2018, 7, x FOR PEER REVIEW 10 of 17 (r = 0.729, p < 0.05) (Figure 3C) and propelargonidin dimers (r = 0.854, p < 0.05) (Figure 3D), while no ﬂavalignans (r = 0.729, p < 0.05) (Figure 3C) and propelargonidin dimers (r = 0.854, p < 0.05) (Figure 3D), correlation was found for flavan-3-ol monomers. Our findings are in agreement with other studies, while no correlation was found for ﬂavan-3-ol monomers. Our ﬁndings are in agreement with other reporting that the antioxidant activity was lower for flavan-3-ol monomers in comparison with studies, reporting that the antioxidant activity was lower for ﬂavan-3-ol monomers in comparison flavan-3-ols of higher degree of polymerization [27,28]. Also, previous studies have revealed that with ﬂavan-3-ols of higher degree of polymerization [27,28]. Also, previous studies have revealed that properlagonidin dimers from U. tomentosa may play a major role in conferring antioxidant capacity properlagonidin dimers from U. tomentosa may play a major role in conferring antioxidant capacity [17]. [17]. Furthermore, ORAC values obtained are similar to those of proanthocyanidin extracts from Furthermore, ORAC values obtained are similar to those of proanthocyanidin extracts from grape grape seeds [22], indicating the potential commercial value of these U. tomentosa extracts. seeds [22], indicating the potential commercial value of these U. tomentosa extracts. Figure 3. Correlation of antioxidant scavenging activity assessed by ORAC method with UPLC Figure 3. Correlation of antioxidant scavenging activity assessed by ORAC method with UPLC quantiﬁcation: (A) Total ﬂavan-3-ols; (B) Procyanidin dimers; (C) Flavalignans-cinchonains and (D) quantification: (A) Total flavan-3-ols; (B) Procyanidin dimers; (C) Flavalignans-cinchonains and (D) Propelargonidin dimers. Propelargonidin dimers. In respect to DPPH, results show correlation between total phenolics determined by UPLC In respect to DPPH, results show correlation between total phenolics determined by UPLC (r = 0.596, p < 0.05) and antioxidant activity measured through DPPH, as well as between (r = −0.596, p < 0.05) and antioxidant activity measured through DPPH, as well as between Folin– Folin–Ciocalteau values (r = 0.635, p < 0.05) and DPPH antioxidant values. Similarly, a correlation Ciocalteau values (r = −0.635, p < 0.05) and DPPH antioxidant values. Similarly, a correlation was was found between these antioxidant results and the PRO values (r = 0.670, p < 0.05). These results found between these antioxidant results and the PRO values (r = −0.670, p < 0.05). These results are in are in agreement with a report on U. tomentosa, showing correlation between antioxidant potency of agreement with a report on U. tomentosa, showing correlation between antioxidant potency of cat’s cat’s claw preparations and their protective ability against DPPH [24]. claw preparations and their protective ability against DPPH [24]. Further, Figure 4 shows the correlation analysis performed for proanthocyanidin subclasses. Further, Figure 4 shows the correlation analysis performed for proanthocyanidin subclasses. Results show a negative correlation with total ﬂavan-3-ols (r =0.601, p < 0.05) (Figure 4A), procyanidin Results show a negative correlation with total flavan-3-ols (r = −0.601, p < 0.05) (Figure 4A), dimers (r = 0.734, p < 0.05) (Figure 4B), ﬂavalignans (r = 0.551, p < 0.05) (Figure 4C), while no procyanidin dimers (r = −0.734, p < 0.05) (Figure 4B), flavalignans (r = −0.551, p < 0.05) (Figure 4C), correlation was found for ﬂavan-3-ol monomers and propelargonidin dimers. Finally, Figure 4D shows while no correlation was found for flavan-3-ol monomers and propelargonidin dimers. Finally, negative correlation results between the antioxidant capacity evaluated through ORAC method and Figure 4D shows negative correlation results between the antioxidant capacity evaluated through DPPH results (r = 0.735, p < 0.05). ORAC method and DPPH results (r = −0.735, p < 0.05). Antioxidants 2018, 7, 65 12 of 18 Antioxidants 2018, 7, x FOR PEER REVIEW 11 of 17 Figure 4. Correlation of antioxidant scavenging activity assessed by DPPH with: (A) Total ﬂavan-3-ols; Figure 4. Correlation of antioxidant scavenging activity assessed by DPPH with: (A) Total flavan-3- (B) Procyanidin dimers; (C) Flavalignans-cinchonains and (D) ORAC antioxidant capacity. ols; (B) Procyanidin dimers; (C) Flavalignans-cinchonains and (D) ORAC antioxidant capacity. 2.4. Principal Component Analysis for Polyphenolic Extracts of U. tomentosa 2.4. Principal Component Analysis for Polyphenolic Extracts of U. tomentosa To summarize the ﬁndings, a statistical Principal Component Analysis (PCA) was performed To summarize the findings, a statistical Principal Component Analysis (PCA) was performed (n = 16) considering 32 individual phenolic compounds as well as TP, PRO, DPPH and ORAC (n = 16) considering 32 individual phenolic compounds as well as TP, PRO, DPPH and ORAC values. values. Two components (PC1 and PC2) were obtained (loadings > 0.18). The ﬁrst component Two components (PC1 and PC2) were obtained (loadings > 0.18). The first component (PC1) (PC1) represented 44.9% of total variance and showed positive correlation to various proanthocyanidin represented 44.9% of total variance and showed positive correlation to various proanthocyanidin compounds, including procyanidin B1, B3, B4, B7 dimers, all four propelargonidin dimers and two compounds, including procyanidin B1, B3, B4, B7 dimers, all four propelargonidin dimers and two ﬂavalignans-cinchonains (at Rt 8.99 and 9.25 min) as well as TP, PRO and ORAC values. The second flavalignans-cinchonains (at Rt 8.99 and 9.25 min) as well as TP, PRO and ORAC values. The second component (PC2) accounted for 16.5% of the total variance and was positively correlated to four acids, component (PC2) accounted for 16.5% of the total variance and was positively correlated to four namely benzoic acid, 4-hydroxybenzoic acid, ferulic acid and isoferulic acid. acids, namely benzoic acid, 4-hydroxybenzoic acid, ferulic acid and isoferulic acid. As illustrated in the plane represented by the two components (Figure 5), bark samples showed As illustrated in the plane represented by the two components (Figure 5), bark samples showed low scores in PC1, representing their lower values for these variables, and they are distributed along low scores in PC1, representing their lower values for these variables, and they are distributed along the second component (PC2) indicating high variability in the contents of the hydroxybenzoic and the second component (PC2) indicating high variability in the contents of the hydroxybenzoic and hydroxycinnamic acids previously cited. In contrast, leaves samples are grouped in the higher score in hydroxycinnamic acids previously cited. In contrast, leaves samples are grouped in the higher score PC1 with larger content of polyphenols (TP), proanthocyanidin (PRO) and ORAC capacity, as well as all in PC1 with larger content of polyphenols (TP), proanthocyanidin (PRO) and ORAC capacity, as well four propelargonidin dimers, procyanidin B1, B3, B4, B7 dimers and the two ﬂavalignans-cinchonains as all four propelargonidin dimers, procyanidin B1, B3, B4, B7 dimers and the two flavalignans- derivatives mentioned above, independently of the extraction procedure. cinchonains derivatives mentioned above, independently of the extraction procedure. Antioxidants 2018, 7, 65 13 of 18 Antioxidants 2018, 7, x FOR PEER REVIEW 12 of 17 Figure 5. Plane deﬁned by two ﬁrst principal components (PC1 and PC2) resulting from the Principal Figure 5. Plane defined by two first principal components (PC1 and PC2) resulting from the Principal component analysis (PCA) of individualized phenolic composition of U. tomentosa phenolic extracts component analysis (PCA) of individualized phenolic composition of U. tomentosa phenolic extracts (n = 16). Extraction: Aq—Aqueous, Et—Ethanolic. Origin: AS—Asomat, LC—Los Chiles, PA—Palacios, (n = 16). Extraction: Aq—Aqueous, Et—Ethanolic. Origin: AS—Asomat, LC—Los Chiles, SR—Sarapiqui. Plant part: B—Bark, L—Leaves. PA—Palacios, SR—Sarapiqui. Plant part: B—Bark, L—Leaves. In sum, our results, using solvents and process adequate for the development of commercial In sum, our results, using solvents and process adequate for the development of commercial products for human consumption, clearly indicate that leaves are the most valuable sources of products for human consumption, clearly indicate that leaves are the most valuable sources of functional polyphenols. Even though most of the commercial preparations are derived from bark functional polyphenols. Even though most of the commercial preparations are derived from bark material, our ﬁndings suggest that leaves represent a more valuable source of proanthocyanidins material, our findings suggest that leaves represent a more valuable source of proanthocyanidins linked to important antioxidant activity and other potential bioactivities [16,17,22]. linked to important antioxidant activity and other potential bioactivities [16,17,22]. 3. Materials and Methods 3. Materials and Methods 3.1. Plant Material, Chemicals and Reagents 3.1. Plant Material, Chemicals and Reagents Uncaria tomentosa samples were collected from different places in Costa Rica: Asomat (El Amparo) Uncaria tomentosa samples were collected from different places in Costa Rica: Asomat (El and Los Chiles (northern part), as well as Palacios (Aprolece) and Sarapiqui (Caribbean part). Vouchers Amparo) and Los Chiles (northern part), as well as Palacios (Aprolece) and Sarapiqui (Caribbean for all plants are deposited in the Costa Rican National Herbarium, under series no. AQ2953, AQ3331, part). Vouchers for all plants are deposited in the Costa Rican National Herbarium, under series no. AQ3332 and AQ3510, respectively. The plant material studied consisted of bark (B) and leaves (L) for AQ2953, AQ3331, AQ3332 and AQ3510, respectively. The plant material studied consisted of bark each location. The material was separated and dried in a stove at 40 C, being turned over every 24 h (B) and leaves (L) for each location. The material was separated and dried in a stove at 40 °C, being for a week until totally dry. The dried material was then ground and preserved in plastic recipients. turned over every 24 h for a week until totally dry. The dried material was then ground and preserved Solvents such as ethanol, methanol, and acetonitrile were purchased from Baker (Center Valley, PA, in plastic recipients. Solvents such as ethanol, methanol, and acetonitrile were purchased from Baker USA). Reagents such as AAPH (2,2-azobis(2-amidinopropane) dihydrochloride), sodium molibdate, (Center Valley, PA, USA). Reagents such as AAPH (2,2-azobis(2-amidinopropane) dihydrochloride), gallic acid, Trolox (6-hydroxy-2,5,7,8-tetramethylchroman-2-carboxylic acid), ﬂuorescein, and sodium sodium molibdate, gallic acid, Trolox (6-hydroxy-2,5,7,8-tetramethylchroman-2-carboxylic acid), tungstate were provided by Sigma-Aldrich (St. Louis, MO, USA). fluorescein, and sodium tungstate were provided by Sigma-Aldrich (St. Louis, MO, USA). 3.2. Extraction of Phenolic Compounds from Bark and Leaves of U. tomentosa 3.2. Extraction of Phenolic Compounds from Bark and Leaves of U. tomentosa The ground dried material from U. tomentosa bark and leaves (n = 8) was extracted (0.05 g/mL) The ground dried material from U. tomentosa bark and leaves (n = 8) was extracted (0.05 g/mL) separately in ethanol at 25 C during 24 h. Afterwards the solvent was removed by ﬁltration and the separately in ethanol at 25 °C during 24 h. Afterwards the solvent was removed by filtration and the extraction process was repeated three times under the same conditions. The ﬁltrates were concentrated extraction process was repeated three times under the same conditions. The filtrates were to dryness using a Buchi™ 215 (Flawil, Switzerland) rotavapor, and the ethanolic extracts were concentrated to dryness using a Buchi™ 215 (Flawil, Switzerland) rotavapor, and the ethanolic preserved at 20 C until extraction. In turn, to obtain the aqueous extracts, each ground dried extracts were preserved at −20 °C until extraction. In turn, to obtain the aqueous extracts, each ground dried material from bark and leaves (n = 8) was extracted (0.05 g/mL) in distilled water, under stirring and heating until reaching 80 °C. After cooling at 25 °C, the solvent was removed by filtration and Antioxidants 2018, 7, 65 14 of 18 material from bark and leaves (n = 8) was extracted (0.05 g/mL) in distilled water, under stirring and heating until reaching 80 C. After cooling at 25 C, the solvent was removed by ﬁltration and the extraction procedure was repeated once. The ﬁltrates were freeze-dried in a Free Zone 105 C, 4.5 L, Cascade Benchtop Freeze Dry System (Labconco, Kansas, MO, USA), and the freeze-dried extracts were preserved at 20 C until extraction. 3.3. Determination of Total Phenolic Content Total polyphenolic contents were evaluated through a variation of the Singleton and Rossi method, as previously described [15], using the Folin–Ciocalteu (FC) reagent, which consists of a mixture of phosphomolybdic and phosphotungstic acids. Brieﬂy, 0.5 mL of a dissolution from each U. tomentosa extract in MeOH (0.1% HCl) was mixed with FC reagent (0.5 mL) and 10 mL of Na CO (7.5%). 2 3 Water was added to complete 25 mL. A similar process was followed to prepare the blank, using 0.5 mL of MeOH (0.1% HCl) instead of extract. Both, extract and blank mixtures were left standing in the dark for 1 h, and afterwards absorbance was measured at 750 nm. Values of total polyphenolic content were obtained by extrapolating absorbances in a gallic acid calibration curve. Analyses were performed in triplicate. Values are expressed as mg gallic acid equivalents (GAE)/g of U. tomentosa extract. 3.4. Total Proanthocyanidin Determination Evaluation of total proanthocyanidin contents was performed through a variation of the Bate–Smith method, consisting of C–C interﬂavanic bond oxidative cleavage, as described early [16]. Brieﬂy, 0.2 mL of a dissolution from each U. tomentosa extract was mixed with 20 mL of butanol/HCl (50:50) and 0.54 mM FeSO . The mixture was incubated at 90 C for 1 h, and then left cooling to 25 C. Afterwards, butanol-HCl mixture was added to complete 25 mL. A similar process was followed to prepare the blank, but without heating. The absorbance of each U. tomentosa extract mixture was measured at 550 nm against the blank. Values of total proanthocyanidin content were obtained by extrapolating absorbances in a cyanidin chloride calibration curve. Values are expresses as mg of cyanidin chloride equivalents/g of U. tomentosa extract. 3.5. Analysis of Phenolic Compounds by UPLC-DAD-ESI-TQ MS To analyze the phenolic composition of U. tomentosa bark and leaves extracts, an UPLC-DAD-ESI-TQ MS system was used, consisting of an UPLC coupled to an Acquity PDA e photodiode array detector (DAD), as well as an Acquity tandem quadrupole (TQD) mass spectrometer equipped with Z-spray electrospray interface (Waters, Milford, MA, USA) U. tomentosa extracts were dissolved in acetonitrile:H O (1:4), for separation on a Waters BEH C18 column (2.1 100 mm; 1.7 m) at 40 C. The ﬂow rate was 0.5 mL/min and the eluent system consisted of a gradient of solvent A—water:acetic acid (98:2, v/v)—and B—acetonitrile:acetic acid (98:2, v/v)—in the following order [15]: 0–1.5 min: 0.1% B, 1.5–11.17 min: 0.1–16.3% B, 11.17–11.5 min: 16.3–18.4% B, 11.5–14 min: 18.4% B, 14–14.1 min: 18.4–99.9% B, 14.1–15.5 min: 99.9% B, 15.5–15.6 min: 0.1% B, 15.6–18 min: 0.1% B. DAD was functioning at 250–420 nm, 1.2 nm resolution and at a 20 point/s rate. ESI was operated in negative mode and ESI parameters comprised: source temperature of 130 C; capillary voltage of 3 kV; desolvation temperature of 400 C; cone and desolvation gas (N ) with ﬂow rates of 60 L/h and 750 L/h respectively. Data were collected in the MRM mode, with speciﬁc transitions of parent and product ions for each compound, whereas external calibration curves were used. Main transitions corresponded to ﬂavan-3-ol monomers (+)-catechin and ()-epicatechin) at m/z 289/245, to dimers of procyanidins at m/z 577/289 and of propelargonidins at m/z 561/289. Also, transitions for procyanidin trimers at m/z 865/577), and ﬁnally for ﬂavanolignans-cinchonains at m/z 451/341. For optimizations, mass detector parameters and calibration curves, commercial standards were used for both ﬂavan-3-ol monomers [() epicatechin and (+)-catechin] and two procyanidin dimers, namely B1 [()-epicatechin-(4 ! 8)-(+)-catechin] and B2 [()-epicatechin-(4 ! 8)-()-epicatechin], as well as for procyanidin trimer C1 Antioxidants 2018, 7, 65 15 of 18 [()-epicatechin-(4 ! 8)-()-epicatechin-(4 ! 8)-()-epicatechin]. For other procyanidin structures such as dimer B3 [(+)-catechin-(4 ! 8)-(+)-catechin], B5 [()-epicatechin-(4 ! 6)-()-epicatechin], and B7 [()-epicatechin-(4 ! 6)-(+)-catechin] work was carried out with standards isolated from other plants and with conﬁrmation by MS/MS spectrum. This method was also applied for procyanidin trimer T2 [()-epicatechin-(4 ! 8)-()-epicatechin-(4 ! 8)-(+)-catechin]. To conﬁrm the structure of ﬂavanolignans and propelargonidins, because of the absence of commercial standards, MS/MS spectrum was achieved for molecular ions at m/z 451 and m/z 561 respectively. In respect to quantiﬁcation for these two types of molecules, this was carried out on the calibration curve of ()-epicatechin and that of procyanidin dimer B1 respectively. Finally, calibration curve of procyanidin B1 was used for quantiﬁcation of procyanidin dimers B2 and B3. The limit of quantiﬁcation (LOQ) and the limit of detection (LOD) of the different standards are published elsewhere [29,30]. The analyses were carried out in triplicate. 3.6. Oxygen Radical Absorbance Capacity (ORAC) The radical scavenging activity of the U. tomentosa phenolic extracts was evaluated through the ORAC method [31]. Brieﬂy, 0.05 g of each U. tomentosa leaves and bark extracts were dissolved in 10 mL of methanol/HCl (1000:1, v/v), then centrifuged (3024 g, 5 min, 5 C) and ﬁltered (0.45 m). The reaction was performed at 37 C in 75 mM phosphate buffer (pH 7.4), whereas the ﬁnal reaction mixture (200 L) comprised ﬂuorescein (70 nM, used as a ﬂuorescence probe), antioxidant (Trolox (1–8 M) or U. tomentosa extract (at different concentrations)) and AAPH (12 mM). AAPH and Trolox solutions were freshly prepared while a ﬂuorescein stock solution (1.17 mM) served to prepare dilutions using 75 mM phosphate buffer (pH 7.4). Black 96-well untreated microplates (Nunc, Denmark) were used for ﬂuorescence determinations in a Polarstar Galaxy plate reader with 520-P emission and 485-P excitation ﬁlters, as well as a Fluorstar Galaxy version v.4.11-0 software (BMG Labtechnologies GmbH, Offenburg, Germany). The 96-well microplate was automatically shaken before the ﬁrst ﬂuorescence reading and afterwards readings were recorded every minute for 98 min. The curve of the blank (no antioxidant) served to normalize the ﬂuorescence measurements. The area under the decay curve (AUC) was calculated from the ﬂuorescence normalized curve, and each sample net AUC was calculated using the formula: Net AUC = AUC AUC . Afterwards, the regression antioxidant blank equation between the antioxidant concentration and the net AUC was estimated. The actual ORAC value for each sample was calculated by dividing the slope of the later equation by the slope of the Trolox equation attained for the same assay. ORAC values were expressed as mmol of Trolox equivalents (TE)/g of U. tonentosa extract. Besides each reaction mixture being performed in duplicate, three independent runs were carried out for each sample. 3.7. DPPH Radical-Scavenging Activity To assess the radical scavenging activity through DPPH method, a 0.25 mM solution of 2,2-diphenyl-1-picrylhidrazyl (DPPH) was prepared in methanol. Then, 0.5 mL of this solution were mixed with 1 mL of polyphenolic samples at different concentrations and the mixture was incubated at 25 C in the dark for 30 min. Blanks were prepared using 1 mL of samples but using 0.5 mL of methanol instead of DPPH. Finally, DPPH absorbance was measured at 517 nm. Each sample was analyzed in three independent assays. Curves of absorbance vs. concentration were plotted to obtain IC , which is the concentration sample needed to get 50% of radical-scavenging activity. 3.8. Statistical Analysis Two-way analyses of variance (ANOVA) were applied to subtotals of phenolic subclasses in order to determine differences in quantitative values in respect to both factors, part of plant and extraction solvents used. On the other hand, in order to evaluate if the total phenolic contents (TP, PRO) and the phenolic subclasses measured by UPLC-DAD/TQ-ESI-MS contribute to the antioxidant activity, a Pearson correlation analysis was carried out between such variables and ORAC values. Finally, Antioxidants 2018, 7, 65 16 of 18 a Principal component analysis (PCA) was applied to summarize the data from the leaves and bark extracts (n = 16) from U. tomentosa taking in consideration 32 individual phenolic contents, TP, PRO, DPPH and ORAC, using the above mentioned Statistical program. 4. Conclusions This paper describes successful methods to obtain enriched polyphenolic extracts of U. tomentosa bark and leaves with solvents adequate for human consumption. Using advanced analytical techniques such as UPLC-DAD/TQ-ESI-MS, results showed selective distribution of 32 non-ﬂavonoid and ﬂavonoid phenolics among the different samples, proanthocyanidins being predominant in leaves, independently of their origin or solvent used. Among proanthocyanidins, propelargonidin dimers are characteristic marker compounds in leaves, showing signiﬁcant correlation with ORAC and DPPH antioxidant activity. PCA analysis also revealed that the phenolic composition of the leaves tends to be less variable than that of barks, also suggesting that leaves constitute a more homogenous material for extraction procedures like the ones used in this study. While most of products already commercialized are pulverized bark material, our results suggest that leaves constitute the part of U. tomentosa more suitable for use in the elaboration of standardize phenolic extracts with potential applications in the nutraceutical industry. Supplementary Materials: The following are available online at http://www.mdpi.com/2076-3921/7/5/65/s1, Figure S1: MRM chromatograms (UPLC-DAD-ESI-TQ-MS) for ﬂavan-3-ols in U. tomentosa extracts. Author Contributions: M.N.-H. and M.M.-J. participated in the conception and design of the study. M.N.-H., M.M.-J., and D.A.-C. were involved in samples preparation, technical work and interpretation of data. I.M.-G. and E.A.-S. were involved in samples acquisition and preparation as well as initial analysis. M.N.-H. drafted the manuscript that was revised and approved by all the authors. Funding: This project was partially funded by grant from the Spanish International Development Cooperation Agency (AECID) (Ref. A/023397/09 and A/030037/10) and a joint grant from the Costa Rica-USA Foundation (CRUSA) and the Spanish Scientiﬁc Research Council (CSIC) (Ref. CR0024). 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This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).

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Polyphenolic Composition and Antioxidant Activity of Aqueous and Ethanolic Extracts from Uncaria tomentosa Bark and Leaves

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Publisher: Multidisciplinary Digital Publishing Institute
ISSN: 2076-3921
DOI: 10.3390/antiox7050065
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Polyphenolic Composition and Antioxidant Activity of Aqueous and Ethanolic Extracts from Uncaria tomentosa Bark and Leaves

Polyphenolic Composition and Antioxidant Activity of Aqueous and Ethanolic Extracts from Uncaria tomentosa Bark and Leaves

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Polyphenolic Composition and Antioxidant Activity of Aqueous and Ethanolic Extracts from Uncaria tomentosa Bark and Leaves

Polyphenolic Composition and Antioxidant Activity of Aqueous and Ethanolic Extracts from Uncaria tomentosa Bark and Leaves

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