Yerba mate is defined as the product constituted by the dried, slightly roasted, and milled leaves of Ilex paraguariensis. However, the fruits of this species are often found in the commercial product. Nowadays the fruits are considered a byproduct. The objective of this work was to obtain the preliminary data of minerals, lipids, methylxanthines and polyphenols in the ripe fruits of I. paraguariensis. The results showed a considerable amount of total dietary fiber (42.0 ± 1.6 g/100 g) and nutritionally valuable minerals: potassium (1324 ± 15 mg/100 g), iron (6.4 ± 0.5 mg/100 g), magnesium (168 ± 15 mg/100 g), calcium (150 ± 12 mg/100 g), copper (1.1 ± 0.1 mg/100 g), zinc (2.3 ± 0.3 mg/100 g), and sodium (1.3 ± 0.1 mg/100 g). The lipid content was 4.5 g/100 g. Oleic acid was the predominant unsaturated fatty acid (38.74 ± 0.75 g/100 g). Linoleic acid (1.83 ± 0,01 g/100 g) was also present. Methylxanthines were quantified: caffeine (0.118 ± 0.001) and theobromine (0.0125 ± 0.0002) g/100 g. The total polyphenol content was 0.717 ± 0.001 g/100 g. The results obtained in this work suggest the potential value of the fruits of I. paraguariensis for the development of novel products in the food and pharmaceutical industries. This paper aims to contribute to the scientific knowledge of a natural by-product from industry regarding the need of foods and medicines for the new millennium.
1. Introduction
Ilex paraguariensis St. Hilaire (Aquifoliaceae) is a native tree from Northeastern Argentina, Southern Brazil, and Eastern Paraguay, where it is also cultivated. It is one of the most known and used species in South America since the product obtained from its industrialization, yerba mate, is used to prepare a tea-like beverage (infusions or decoctions) that is appreciated for its peculiar flavour and stimulating, antioxidant, choleretic, and nutritional properties [1, 2]. The leaves are also used in folk medicine to treat arthritis, headache, constipation, rheumatism, obesity, fatigue, fluid retention, and liver disorders. This species is exported to Europe, US, Syria, and Japan where it is marketed as a milled plant or extracts used in herbal formulations and functional food products with stimulating, diuretic, antioxidant, and weight-reducing properties. Yerba mate is included in Codex Alimentarius, Argentine Food Code, Latin-American Food Code, and the main scientific acknowledgment Pharmacopoeias (Martindale, British Herbal Pharmacopoeia, German Commission E Monographs) [3]. Nowadays it is also considered a functional food [4]. According to the Argentine Food Code (CAA), yerba mate is defined as the product constituted exclusively by the dried, slightly roasted, and milled leaves of I. paraguariensis which can contain fragments of young branches, pedicles, and floral peduncles. However and as a result of the elaboration process, the fruits of this species may be present in the final product which has been consumed over centuries. The fruit is in a nucule and can reach a diameter of approximately 7 mm; there are four or five single-seed pyrenes (propagules). Mate flowers from October to November and fruiting occurs from December to May. During the ripening process, the fruit color changes from green to white, reddish-brown, and finally black when it is fully ripe. There is a rudimentary embryo in many externally ripe seeds which causes a long period of germination.
The maximum allowed content of fruit or organic material in the final product is 1 g/100 g [5]. The great quantity of fruits remaining after the yerba mate processing is discarded.
Argentina is the main yerba mate producer country, with nearly 280000 tons per year followed by Brazil and Paraguay. The worldwide production of yerba mate has ascended to 874678 tons in 2002 [6]. Nonofficial data suggest that Argentina could generate about 560 tons per year of fruits, and the global annual production could exceed 1700 tons per year. Nowadays the fruits have no economic value and they are treated as waste and used as fertilizer.
The objective of this work was to assess the preliminary data on the nutritional valuable elements, the methylxanthines and total polyphenol content of the ripe fruits of I. paraguariensis in order to study their potential value as a source of ingredients to be used in the food and pharmaceutical industries.
2. Materials and methods2.1. Plant Material
Ripe fruits of I. paraguariensis were provided by a “yerba mate” factory located in Gobernador Valentín Virasoro in the province of Corrientes, Argentina. The production process of yerba mate involves the harvest of the green leaves and small stems of this species which contain fruits. They are cut manually, put into 100 kg sacks, and then carried to the factory. After harvesting, they were submitted to a roasting process named “sapecado” (exposition to direct fire at temperatures between 250°C and 550°C during 2–4 min) and then to a drying process (exposition to a current of hot air until a 3-4% of moisture is reached).
The fruits analyzed in this work were harvested in April 2009. They were dark reddish-brown in color, with a diameter of 4 to 6 mm. They were identified by PhD. Gustavo Gibeti, botanical specialist in Ilex spp. Comparison with voucher specimens of herbarium standards was done. A sample was deposited in the Herbarium Botany Unit of the Faculty of Pharmacy and Biochemistry of the University of Buenos Aires under number BACP: BAF 2 (series 2010). In our laboratory, the fruits were dried in a stove with hot air circulation and thermostatized at 40°C (until 2% of moisture was reached) and then milled to fine powder with a cutter mill with 1 mm pore mesh.
2.2. Standards and Reagents
Standard solutions CertiPUR Merck Chemicals International were employed for the determination of the mineral content. A mixture of fatty acid methyl esters standards from SUPELCO FAME Mix NHI-C and FAME Mix C4–C24 were purchased from Sigma-Aldrich, Buenos Aires, Argentina. Standards of caffeine and theobromine were purchased from Sigma-Aldrich, Argentina. All solvents and reagents used in the experimental work were analytical-grade chemicals except those used in the high-resolution analytical methods which were HPLC grade and purchased from Merck Chemicals Argentina.
2.3. Proximate Analysis
The recommended methods of the Association of Official Analytical Chemists [8] were adopted to determine the levels of moisture, ash, protein, crude fat, and total dietary fiber. The moisture content was determined by heating 5.0 g of each sample to a constant weight in a crucible placed in an oven maintained at 70°C under pressure (≤50 mm Hg). Ash was determined by calcinations of 3.0 g of each sample placed in muffle furnace maintained at 550°C until constant weight. Protein (% total nitrogen× 6.25) was determined by the Kjeldahl method using 1.0 g samples. Fat content was determined gravimetrically after petroleum ether extraction (boiling point range 35–65°C) of 5.0 g samples.
Total dietary fiber (TDF) was determined by the enzymatic-gravimetric method [9]. The total carbohydrate content was defined as the residue, excluding protein, lipid, TDF, and ash, and was calculated as follows:
(1)Total carbohydrate = 100 -(% moisture + % ash+ % Protein+ % lipid + % TDF).
2.4. Mineral Content
Test samples (0.5 g) were digested in 15 mL HNO3/HCLO4 (2 : 1, v/v) according to AOAC [8], and sodium, potassium, calcium, magnesium, copper, iron, and zinc were determined by atomic absorption spectrophotometry (Perkin–Elmer model AA400).
2.5. Fatty Acids Extraction
Milled fruits (aprox. 9.0 g) were homogenized and lipids were extracted with n-hexane by lixiviation until total extraction [10]. The organic solvent was evaporated under vacuum and the oil obtained was esterified. Methyl esters were prepared by transmethylation according to the procedure of the International Organization for Standardization (ISO) [11] and analyzed by gas chromatography (GC).
2.6. Gas-Liquid Chromatography
The fatty acid methyl esters were analyzed using a Clarus 500 Perkin Elmer gas chromatography device equipped with a flame ionization detector (FID) and the TotalChrom software. A fused silica capillary column SP 2560 (Supelco Park, Bellefonte, PA, USA) (100 m × 0.25 mm and 0.20 μm) was employed. The column temperature was programmed as follows: 150°C (1 min), a gradient ranging from 150°C to 210°C for 20min at a rate of 5°C/min. The injection port and detector were maintained at 240°C and 280°C, respectively. As carrier gas nitrogen was employed at a gas linear speed of 1.3 mL min−1. The individual fatty acids were identified by comparison of retention times and peak areas with those of known mixtures of fatty acid methyl esters (FAMEs) standards.
2.7. Methylxanthines Extraction
Briefly, 500 mg of each sample were placed in a 250 mL round-bottom flask containing 50 mL of methanol and extracted during 30 minutes under a reflux condenser and then filtered. The residue was subjected to the same procedure twice. The filtrates were then combined and dried in a rotary evaporator [12]. The extract obtained was solubilized in 20 mL of water: acetic acid (98 : 2) and transferred to a 25 mL flask. Methanol was added to reach a final volume. A 45 μm filter (Millipore) was used to filter the extract before HPLC analysis.
2.8. High Performance Liquid Chromatography
A Varian series 9000 equipment with a Varian 9012 binary pump was used. Quantitation of methylxanthine was done using validated HPLC external standard methods [13]. A reverse-phase IB-SIL RP 18 (5 μm, 250×4.6 mm I.D.) Phenomenex column and an elution gradient consisting of solvent A: water : acetic acid (98 : 2) and solvent B: methanol : acetic acid (98 : 2) were used. The elution gradient was: from 17% B to 20% B, 10 min; 20% B (isocratic), 5 min; 20% B to 23% B, 10 min; 23% B to 100% B, 5 min with a flow rate of 1.0 mL·min−1. Identification and quantitation were carried out by simultaneous detection with an UV Varian 9050 UV detector and a Varian 9065 photodiode array detector operating at 273 nm. Samples were injected with a Rheodyne injector fitted with a 100 μL loop.
2.9. Total Polyphenol Determination
The total polyphenol content was determined by spectrophotometry according to the Folin-Ciocalteu method [14] using gallic acid as standard. Exactly around 1.0 mg of methanolic extract was weighted and dissolved in 10 mL of deionized distilled water. Briefly, 1.0 mL of this sample extract was transferred in duplicate to separate tubes containing 7.0 mL distilled water, 0.5 mL of Folin-Ciocalteu’s reagent, and 1.5 mL of a 20% sodium carbonate anhydrous solution (added 2 min after the Folin–Ciocalteu’s reagent). The tubes were then allowed to stand at room temperature for 60min and then the absorbance at 765 nm was measured by employing a UV-Vis spectrophotometer (Shimadzu UV 2101). The concentration of polyphenols in samples was derived from a standard curve of gallic acid ranging from 10 to 50 μg/mL (Pearson’s correlation coefficient: r2=0,9996).
2.10. Statistical Analysis
Data were expressed as means ± standard error of the mean of three independent experiments of the same batch carried out by triplicate.
3. Results and Discussion3.1. Proximate Analysis
The results of moisture content, ash, lipids, proteins, carbohydrates, and fiber are presented in Table 1. The fruits presented considerable amounts of total dietary fiber (TDF) (42.0 g/100 g) and carbohydrates (38.3 g/100 g).
Proximate composition of the fruits of Ilex paraguariensis.
Composition
g/100 g raw fruit, dry weight
Moisture
5.9±0.1
Ash
3.8± 0.2
Protein (N×6.25)
5.5±0.1
Lipid yield
4.5± 0.3
Total dietary fiber (TDF)
42.0±1.6
Insoluble dietary fiber (IDF)
37.6 ±1.3
Soluble dietary fiber (SDF)
4.4 ±0.3
Carbohydrate
38.3 ±1.2
Results are expressed as the Means ± SEM of three experiments performed in triplicates. The fiber content has been corrected for protein and ash. The carbohydrate was defined as the residue, excluding protein, lipid, TDF, and ash, and was calculated by difference as follows:
Since the mid- 1970s, the role of dietary fibers in health and nutrition has received considerable attention [15]. The consumption of dietary and functional fibers has many potential health benefits, namely, the ability to lower the incidence of constipation [16] and irritable bowel syndrome [17], to lower cholesterol levels and diminish the incidence of coronary and cardiovascular heart diseases [18, 19] to prevent obesity [20] and the development of diabetes [21], to avoid colon cancer [22], and to increase survival of patients with breast cancer [23].
Dietary fiber-rich products have gained popularity as food ingredients to obtain health benefits and have encouraged food scientists to search for new fiber sources as well as to develop high-fiber products [24].
In the agricultural byproducts of some fruits and greens (apple pomace, citrus fruits, olive cake and oat, among others), TDF content ranges from 10.2 to 87.9 g/100 g [25, 26]. In this work, the insoluble dietary fiber (IDF) (37.6 g/100 g) was the predominant fiber fraction (89.5% of TDF). Similar results were reported for pear pomace (IDF: 82.7% of TDF) and apple pomace (IDF: 77.3% of TDF) [26].
The crude protein content was found to be 5.5 g/100 g and the crude lipids 4.5 g/100 g dry matter. The lipid content is similar to that reported for the aerial parts of legumes, which is about 4-5g/100 g dry matter [27].
3.2. Mineral Content
The mineral content (sodium, potassium, iron, copper, zinc, calcium, and magnesium) was determined. I. paraguariensis fruits contain significant amounts of essential minerals that are associated with improved health status when consumed at doses beyond those necessary for preventing a deficiency state. The results obtained in this work are presented in Table 2. As it is shown, the most abundant mineral elements were potassium, iron, and magnesium which represent the 66%, 64%, and 48% of the daily allowances recommended for adults in the 25–50 year age range [7] (Table 2). The high quantity of these elements together with the quantity of calcium and the content of the essential elements zinc and copper allow the fruits to be considered as excellent sources of bioelements [28].
Mineral composition of the fruits of Ilex paraguariensis.
Element
mg/100 g of dry matter
RDA(1)
% RDA(2)
Sodium
1.3 ± 0.1
500
0
Potassium
1324 ± 15
2000
66
Iron
6.4 ± 0.5
10
64
Copper
1.1 ± 0.1
0.9
122
Zinc
2.3 ± 0.3
15
14
Calcium
150 ± 12
800
19
Magnesium
168 ± 15
350
48
Results are expressed as the Means ± SEM of three experiments performed in triplicates.
(1)RDA (NAS/NRC) [7] based on the recommended daily allowances for adults in the 25–50 age range.
(2)% RDA (Mean contribution for mineral requirements in terms of RDA (NAS/NRC) [7].
3.3. Fatty Acid Analysis
The yield of fatty acids obtained from the fruits was 4.5±0,3 g/100 g, where oleic acid as the predominant unsaturated fatty acid reaching a 38.74 g/100 g. Linoleic acid, one of the most important polyunsaturated fatty acids in human food and was also present (1.83±0,01%). Linoleic acid prevents cardiovascular disorders high blood pressure and is part of the structural components of the plasma membrane [29]. Palmitic and stearic acids were also found at high levels in the lipidic fraction (Table 3).
Fatty acid composition(1) of the fruits of Ilex paraguariensis.
Fatty acid
%(1)
C 6 : 0
2.12 ± 0.16
C 8 : 0
0.68 ± 0.07
C 14 : 0
0.14 ± 0.01
C 16 : 0
30.57 ± 0.79
C 16 : 1
0.38 ± 0.01
C 17 : 0
0.99 ± 0.15
C 18 : 0
12.28 ± 0.19
C 18 : 1 trans
0.73 ± 0.23
C 18 : 1
38.74 ± 0.75
C 18 : 1 cis
0.65 ± 0.03
C 18 : 2 trans
2.21 ± 0.11
C 18 : 2
1.83 ± 0.01
C 20 : 0
0.76 ± 0.01
C 20 : 1
0.24 ± 0.01
C 22 : 0
0.17 ± 0.01
C 24 : 0
0.15 ± 0.03
Total saturated
47.86
Total monounsaturated
40.01
Total polyunsaturated
1.83
Trans fatty acids
2.94
Nonidentified minor components
7.36
(1)Percent by weight of total fatty acids identified by GC as fatty acids methyl esters (FAME).
Results are expressed as the means ± SEM of three experiments performed in triplicates.
3.4. Methylxanthine Content
Caffeine and theobromine were identified and quantified. Theophylline was not detected. Results are presented in Table 4. The presence of caffeine in the unripe fruits of this plant has been reported previously and was found to be 0.04 g/100 g [30]. The caffeine and theobromine content (0.118±0.001%) and (0.0125±0.0002) found in this work were higher than those reported by other authors. For example, Schubert et al. [31], who also investigated the unripe fruits, reported an amount of 1.16±0.06 mg/g of total methylxanthines, a value which is also lower than our results. These discrepancies could be due to the fact that our material consisted in the ripe fruits of I. paraguariensis and the results previously reported were obtained from the unripe ones. This is the first study on the methylxanthines content in the ripe fruits of I. paraguariensis.
Methylxanthine content in the fruits of Ilex paraguariensis.
Methylxanthine
g/100 g raw fruit, dry weight
Caffeine
0.118 ± 0.001
Theobromine
0.0125 ± 0.0002
Data are expressed as the means ± SEM of three independent experiments carried out in triplicates.
The values were obtained by HPLC with DAD. Theophylline was not detected. Detection limit: 1 ppm.
3.5. Total Polyphenol Determination
The total polyphenol content found in this work was 0.717±0.001 g/100 g gallic acid equivalents, dry wet. The amount of polyphenols found here was higher than those reported by other authors who studied the unripe fruits. Schubert et al. [31] found 54.25±1×10-3 to 110.36±4×10-4 4 mg/g. Borré et al. [30] found 0.03% of chlorogenic acid. These differences could indicate that the ripe fruits contain higher amounts of polyphenols than the unripe ones. This is the first study on the polyphenol content in the ripe fruits of I. paraguariensis.
4. Conclusions
This paper aims to contribute to the scientific knowledge of a natural by-product from industry regarding the need of foods and medicines for the new millennium.
The results obtained in this work suggest the potential value of the fruits as a fiber and valuable mineral source. These fruits could also be a source of bioactive compounds such as methylxanthines and polyphenols. The utilization of this material could become profitable and at the same time help to minimize waste disposal problems. The results obtained in this work suggest the potential value of the fruits of Ilex paraguariensis for the development of novel products in the food and pharmaceutical industries.
Acknowledgment
This work was supported by Grant UBACYT 20020100100158 from the University of Buenos Aires.
FilipR.SebastianT.FerraroG.AnesiniC.Effect of Ilex extracts and isolated compounds on peroxidase secretion of rat submandibulary glands20074546496552-s2.0-3384687563610.1016/j.fct.2006.10.014GorzalczanyS.FilipR.AlonsoM. D. R.MiñoJ.FerraroG. E.AcevedoC.Choleretic effect and intestinal propulsion of “mate” (Ilex paraguariensis) and its substitutes or adulterants2001752-32912942-s2.0-003507335010.1016/S0378-8741(01)00179-9FilipR.FerraroG. E.Researching on new species of “mate”: Ilex brevicuspis: phytochemical and pharmacology study200342150542-s2.0-003721784510.1007/s00394-003-0399-1IsolabellaS.CogoiL.LópezP.AnesiniC.FerraroG.FilipR.Study of the bioactive compounds variation during yerba mate (Ilex paraguariensis) processing201012236956992-s2.0-7795162415210.1016/j.foodchem.2010.03.039CAACódigo Alimentario Argentino(Argentine Food Code), Artículo 1193–1198http://www.anmat.gov.ar/alimentos/codigoa/Capitulo_XV.pdfHeckC. I.de MejiaE. G.Yerba mate tea (Ilex paraguariensis): a comprehensive review on chemistry, health implications, and technological considerations2007729R138R1512-s2.0-3634903117510.1111/j.1750-3841.2007.00535.xRDANAS/NRC198910thWashington, DC, USANational Academy of Sciences/National Research CouncilAssociation of Official Analytical Chemists200017thWashington, DC, USAAssociation of Official Analytical ChemistsProskyL.AspN. G.SchweizerT. F.DeVriesJ. W.FurdaI.Determination of insoluble, soluble, and total dietary fiber in foods and food products: interlaboratory study1988715101710232-s2.0-0024084787RamadanM. F.SharanabasappaG.ParmjyothiS.SeshagiriM.MoerselJ. T.Profile and levels of fatty acids and bioactive constituents in mahua butter from fruit-seeds of buttercup tree [Madhuca longifolia (Koenig)]20062225-67107182-s2.0-3364488549310.1007/s00217-005-0155-2ISOInternational organization for standardization: animal and vegetable fats and oils1978010620053rdMonografía Nuez de colaFilipR.LópezP.CoussioJ.FerraroG.Mate substitutes or adulterants: study of xanthine content199812212913110.1002/(SICI)1099-1573(199803)12:2<129::AID-PTR191>3.0.CO;2-1SingletonV. L.RossiJ. A.Colorimetry of total phenolics with phosphomolybdic phosphotungstic acid reagents1965163144158Abdul-HamidA.LuanY. S.Functional properties of dietary fibre prepared from defatted rice bran200068115192-s2.0-034411760410.1016/S0308-8146(99)00145-4CastillejoG.BullóM.AngueraA.EscribanoJ.Salas-SalvadóJ.A controlled, randomized, double-blind trial to evaluate the effect of a supplement of cocoa husk that is rich in dietary fiber on colonic transit in constipated pediatric patients20061183e641e6482-s2.0-3374906953810.1542/peds.2006-0090MalhotraS.RanaS. V.SinhaS. K.KhuranaS.Dietary fiber assessment of patients with irritable bowel syndrome from northern India20042362172182-s2.0-11844307175RomeroA. L.WestK. L.ZernT.FernandezM. L.The seeds from Plantago ovata lower plasma lipids by altering hepatic and bile acid metabolism in guinea pigs20021326119411982-s2.0-0036276713Van RosendaalG. M. A.ShafferE. A.EdwardsA. L.BrantR.Effect of time of administration on cholesterol-lowering by psyllium: a randomized cross-over study in normocholesterolemic or slightly hypercholesterolemic subjects20043, article 172-s2.0-544426122510.1186/1475-2891-3-17MurakamiK.SasakiS.OkuboH.TakahashiY.HosoiY.ItabashiM.Dietary fiber intake, dietary glycemic index and load, and body mass index: a cross-sectional study of 3931 Japanese women aged 18–20 years20076189869952-s2.0-3394749890410.1038/sj.ejcn.1602610HannanJ. M. A.AliL.RokeyaB.KhalequeJ.AkhterM.FlattP. R.Abdel-WahabY. H. A.Soluble dietary fibre fraction of Trigonella foenum-graecum (fenugreek) seed improves glucose homeostasis in animal models of type 1 and type 2 diabetes by delaying carbohydrate digestion and absorption, and enhancing insulin action20079735145212-s2.0-3404725410210.1017/S0007114507657869WakaiK.DateC.FukuiM.TamakoshiK.WatanabeY.HayakawaN.KojimaM.KawadoM.SuzukiK.HashimotoS.TokudomeS.OzasaK.SuzukiS.ToyoshimaH.ItoY.TamakoshiA.Dietary fiber and risk of colorectal cancer in the Japan collaborative cohort study20071646686752-s2.0-3424753285110.1158/1055-9965.EPI-06-0664McEligotA. J.LargentJ.ZiogasA.PeelD.Anton-CulverH.Dietary fat, fiber, vegetable, and micronutrients are associated with overall survival in postmenopausal women diagnosed with breast cancer20065521321402-s2.0-3375089425310.1207/s15327914nc5502_3SchaafsmaG.van der KampJ. M.AspN. G.MillerJ.SchaafsmaG.Health claims, options for dietary fiber2004Wageningen, the NetherlandsAcademic Publishers2738Grigelmo-MiguelN.Martín-BellosoO.Characterization of dietary fiber from orange juice extraction19983153553612-s2.0-003210536910.1016/S0963-9969(98)00087-8LaufenbergG.KunzB.NystroemM.Transformation of vegetable waste into value added products: (A) the upgrading concept; (B) practical implementations20038721671982-s2.0-003737499210.1016/S0960-8524(02)00167-0AjayiI. A.OderindeR. A.KajogbolaD. O.UponiJ. I.Oil content and fatty acid composition of some underutilized legumes from Nigeria20069911151202-s2.0-3364602224110.1016/j.foodchem.2005.06.045Saura-CalixtoF.CañellasJ.Mineral composition of almond varieties (Prunus amygdalus)198217421291312-s2.0-034346378410.1007/BF01045828OmodeA. A.FatokiO. S.OlaogunK. A.Physicochemical properties of some underexploited and nonconventional oilseeds19954311285028532-s2.0-0001292664BorréG. L.KaiserS.PaveiC.da SilvaF. A.BassaniV. L.OrtegaG. G.Comparison of methylxanthine, phenolics and saponin contents in leaves, branches and unripe fruits from Ilex paraguariensis A. St. Hil. (mate)20103333623742-s2.0-7644909261110.1080/10826070903526055SchubertA.PereiraD. F.ZaninF. F.AlvesS. H.BeckR. C. R.AthaydeM. L.Comparison of antioxidant activities and total polyphenolic and methylxanthine contents between the unripe fruit and leaves of Ilex paraguariensis A. St. Hil200762118768802-s2.0-3634896062310.1691/ph.2007.11.7052