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Bioactive Constituents, Metabolites, and Functions
Comprehensive study of phenolic compounds profile and antioxidant activity of eight pistachio cultivars, their residual cakes and virgin oils Rosa Maria Ojeda-Amador, M. Desamparados Salvador Moya, Giuseppe Fregapane, and Sergio Gómez-Alonso J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.8b06509 • Publication Date (Web): 01 Mar 2019 Downloaded from http://pubs.acs.org on March 1, 2019
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Journal of Agricultural and Food Chemistry
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Comprehensive study of phenolic compounds profile and antioxidant
2
activity of eight pistachio cultivars, their residual cakes and virgin oils
3
M.
Ojeda-Amadora,
4
Rosa
María
Desamparados
5
Fregapanea, Sergio Gómez-Alonsoa,b*,
6
aDepartamento
7
Universidad de Castilla-La Mancha, Ciudad Real, Spain
8
bInstituto
9
La Mancha, Ciudad Real, Spain
Salvadora,
Giuseppe
de Tecnología de Alimentos, Facultad de Ciencias Químicas,
Regional de Investigación Científica Aplicada, Universidad de Castilla-
10 11
*Corresponding author: Sergio Gómez Alonso:
[email protected] 12 13 14
Other authors e-mails:
15
Rosa M. Ojeda-Amador:
[email protected] 16
María Desamparados Salvador,
[email protected] 17
Giuseppe Fregapane,
[email protected] 18 19 20 21 22 23 24 25 26 27 28 29 30
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Abstract
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Phenolic compounds of eight pistachio (Pistacia vera L.) cultivars, their residual
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cakes and virgin oils (screw pressing) were studied using HPLC-DAD-ESI-
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MS/MS. A total of 25 compounds were identified and quantified for pistachio nuts
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and residual cakes, being reported for the first time the presence of five flavonols,
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six flavanols and one gallotannin. Total phenolics in pistachio nuts showed a
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concentration from 1359 mg/kg (Kastel) to 4507 mg/kg (Larnaka). Flavanols were
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the most abundant phenolics, about 90%, resulting procyanidin B1 and
39
gallocatechin the main ones, depending on the cultivar. Other phenolic groups
40
such as anthocyanins (from 54 to 218 mg/kg), flavonols (from 76 to130 mg/kg),
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flavanones (from 12 to 71 mg/kg) and gallotannins (from 4 to 46 mg/kg) were also
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identified. Residual cakes presented the same phenolic profile, but with a
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concentration almost double because of the concentration effect caused by the
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oil separation. Virgin pistachio oils showed a very low phenolic content, being
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eriodyctiol the only compound identified.
46 47
Keywords: pistachio; by-product; residual cake; virgin oil; phenolic compounds;
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antioxidant activity.
49 50
Abbreviations: High Performance Liquid Chromatography (HPLC), Diode Array
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Detector (DAD), Electrospray Ionization (ESI), Mass Spectrometry (MS), 2,2-
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diphenyl-1-(2,4,6-trinitrophenyl)hydrazyl (DPPH), oxygen radical absorbance
53
capacity (ORAC), 2,2’-azobis(2-amidinopropane) dihydrochloride (AAPH), Trolox
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Equivalent (TE), Retention time (Rt), ultraviolet-visible (UV-vis), Fresh weigh
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(FW), Procyanidin B1 (PB1), Procyanidin B2 (PB2), Analysis of Variance
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(ANOVA) and Principal Component Analysis (PCA).
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1. INTRODUCTION
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Pistacia vera L., is a plant of the Anacardiaceae family known since prehistoric
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times. It was originated in western Asia and its cultivation spreads to the
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Mediterranean basin through Iran, which has been the major crop producer for a
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long time1. The top worldwide producer in 2014 was Iran (415,000 tons), followed
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by United States (230,000 tons) and Turkey (80,000 tons)2. In Spain orchards
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have been planted since 1996, contributing in 2016 with more than 15,000 ha
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with a production over 1,000 tons, being placed 80% of the cultivation in the
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region of Castilla-La Mancha3.
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Pistachios are rich in protein and fat, with a balanced content of mono- (~70%)
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and polyunsaturated (~20%) fatty acids, which could result in the reduction of
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both, LDL levels and therefore the risk of coronary heart disease4. Moreover, they
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present a high content of bioactive compounds, such as tocopherols, phytosterols
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and phenolic compounds5,6, being this kind of nuts among the top fifty foods with
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a high antioxidant potential7. Some bioactive compounds present in pistachios
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have been reported to present a rapid accessibility in the stomach, thereby
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contributing to the beneficial relationship between pistachio consumption and
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health-related outcomes8.
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Since few years ago, several studies have reported the chemical composition of
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pistachios9,10 not only because of their properties but also for their geographic
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origin differentiation11. However, there are very few publications related to the
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comprehensive study of pistachios phenolic profile, which include anthocyanins,
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flavonoids, flavanones, phenolic acids, flavanols and isoflavones12-14.
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The most important use of pistachio nuts has traditionally been as snack, but it
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has been also employed in a wide range of manufactured formulations into the
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food industry, such as ice-creams, bakery, desserts and cold cuts15. Nowadays,
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virgin edible oils as foodstuffs are emerging as an alternative related to the
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interest of people about consuming beneficial healthy products and less-
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processed foods16. Within these kind of oils, stand out those obtained from nuts,
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which have recently appeared in the market. Virgin tree nut oils are very
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appreciated in gastronomy because of their typical aroma, taste and nutritional
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characteristic, which depends on the extraction technology and processing
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conditions, as roasting17. The by-product obtained after pressing, may be used
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as a partially defatted product, rich in proteins and carbohydrates, for applications
95
such as specialty baking, energy bars and animal feeds. Moreover, recent
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evidences about their high content in bioactive substances as phenolic
97
compounds10,18 could make it possible the development of new applications as
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functional ingredients.
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To the best of our knowledge, no data related to differences in the phenolic profile
100
of diverse Pistacia vera L. cultivars grown under the same agronomical conditions
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are reported in bibliography, even though this is one of the most important factor
102
that affects phenolic composition of fruits and vegetables as olive19 and walnuts20.
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In this sense, this study aims to complete the information about phenolic profile
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and antioxidant activity in pistachio nuts from eight different cultivars grown under
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the same agronomical conditions, employing a HPLC-DAD-ESI-MS/MS, as well
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as in the virgin oil and the by-product obtained after pressing. On the other hand,
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a complete characterization of phenolic profile of residual cakes from pistachios
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has been carried out.
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2. MATERIALS AND METHODS
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2.1. Experimental pistachio orchards: the study was carried out during the crop
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season 2014/2015 in an experimental pistachio orchard where different pistachio
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cultivars were grown. Eight Pistacia vera L. varieties (Aegina, Avdat, Kastel,
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Kerman, Larnaka, Mateur, Napoletana and Sirora; 10–15 kg each) were provided
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by the regional research centre ‘Centro de Mejora Agraria El Chaparrillo-IRIAF’,
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located in Ciudad Real (Spain; 39⁰ 00' 17" N, 3⁰ 57' 44" W, elevation 628 m.a.s.l).
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The soil at the experimental site is a shallow clay-loam (Alfisol Xeralf Petrocalcic
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Palexeralfs) with a depth of 1.3 m and a discontinuous petrocalcic horizon
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between 0.75 and 0.85 m. The trees were spaced 5 m × 5 m apart (400 trees
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ha−1). This area shows a Mediterranean continental climate, with an average
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annual rainfall about 400 mm, mostly distributed outside of a 4-month (June-
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September) summer drought period. The total rainfall in Ciudad Real was 324
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mm during the 2014/2015 hydrological years (Oct-Sep). All agronomical
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treatments applied to the experimental pistachio orchards were identical and no
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irrigation treatment was applied.
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2.2. Virgin pistachio oil and by-product extraction: the oil was extracted using
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a screw press (Komet Screw Vegetable Oil Expeller CA59G-CA563, IBG
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Monforts Oekotec GmbH & Co. KG, Mönchengladbach, Germany) equipped with
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a 6 mm diameter nozzle and operating at a screw speed of 30 rpm. The screw
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press was first run empty for 10–15 min to raise the screw-press barrel
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temperature to the minimum required for extracting the oil (about 50 ⁰C) using
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the electrical resistance ring attached around the press barrel10. The resulting
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crude oil (approximately 1.0–1.2 L of each variety) was centrifuged at 5000 rpm
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to remove the residual plant material. Oil samples were stored in amber bottles,
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without headspace, to protect them from light. The residual cakes were placed in
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labelled pouches and vacuum-packed to prevent any oxidative degradation. All
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samples were stored in the dark at 4 ⁰C until analysed. The extraction yield of the
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screw press process was ranged between 52.7-72.7%, depending on the variety.
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2.3. Phenolic extracts preparation: 0.4 g of ground pistachio nut or residual
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cake were first mix two times with n-hexane (6 + 4 mL) for removing fat, being
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discarded this fraction after centrifugation. Then, a double extraction of the solid
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residue obtained from the n-hexane extraction was performed in 20 mL
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MeOH:H2O:HCOOH (80:20:0.1; 10 + 10 mL), with 2 min vortex, followed by 5 min
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ultrasound and centrifugation at 2000 g for 10 min. The combined hydro-
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methanolic extracts were filtered with a 0.45 µm nylon syringe filter and stored at
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-20 ºC until use.
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Virgin oil (5 g) was dissolved in n-hexane (10 mL) and 10 ml of
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MeOH:H2O:HCOOH (80:20:0.1) were added. The mixture was vortexed for 2 min,
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followed by 5 min of ultrasound and then centrifuged at 2000 g for 10 min. Finally,
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the polar fraction was separated and filtered with a 0.45 µm nylon syringe filter
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and stored at -20 ºC until use.
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2.4. Antioxidant activity was evaluated by measuring the radical scavenging
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effect of the methanolic extract toward the synthetic radical 2,2-diphenyl-1-(2,4,6-
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trinitrophenyl)hydrazyl (DPPH), as reported previously21,22. Briefly, 100 µl of the
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polar extract, prepared according to point 2.3, was added to a methanolic DPPH
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solution (2.9 ml, 6·× 10-5 M) and stored in the dark for 30 min. The decrease in
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absorbance of the resulting solution was then measured at 515 nm using an
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Agilent 8453 spectrophotometer. A calibration curve was constructed using
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Trolox as the external standard and results are expressed as of the assays are
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expressed as mmol Trolox Equivalents per kg of pistachio (kernel, cake or oil),
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mmol TE/kg.
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Furthermore, the oxygen radical absorbance capacity (ORAC) was assessed23
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by preincubation of 20 µl of polar extract and 120 µl of fluorescein (70 nM) at
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37°C for 15 min. Then, 60 µl of 24 mM 2,2’-azobis(2-amidinopropane)
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dihydrochloride (AAPH) was added and the mixture incubated at 37°C,
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measuring fluorescence every minute for 80 min, with a pre-measurement
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agitation at maximum intensity for 10 s. The experiment was carried out in
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Nunclon black 96-well flat-bottom plates (Sigma-Aldrich, Madrid, Spain) and
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measurements acquired using a plate reader with emission and excitation filters
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set at 528 and 485 nm, respectively (Synergy HT, Bio-Tek; Vermot, USA). The
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fluorescence curves were normalized with respect to the blank curve (without
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antioxidant). The calibration curve was prepared using Trolox as the external
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standard and results of the assays are expressed as mmol Trolox Equivalents
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per kg of pistachio (kernel, cake or oil), mmol TE/kg.
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2.5. Analysis of phenolic compounds by HPLC-DAD-MSn. Aliquots (1.75 mL)
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of phenolic extracts were evaporated to dryness in a rotary evaporator at 35 °C
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under vacuum, and then redissolved in 200 µL of methanol/water (20:80, v/v) by
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sonicating (5 min.) and vortexed (2 min) before injecting 20 µL in the HPLC
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system.
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Individual phenolic compounds were determined by an HPLC-DAD-ESI-MS/MS
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method adapted from conditions previously described24. The analysis was
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performed on an Agilent 1100 series system (Agilent, Waldbronn, Germany)
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equipped with a photodiode array detector (DAD) and an LC/MSD Trap VL
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electrospray ionization mass spectrometry (ESI-MS/MS), both coupled with an
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Agilent ChemStation for data processing.
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Separation of phenolic compounds was achieved on a narrow-bore column
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Zorbax Eclipse XDB-C18 (2.1 x 150 mm; 3.5 µm particle; Agilent), with pre-
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column Zorbax Eclipse XDB-C8 (2.1 x 12.5 mm; 5 µm particle; Agilent), both
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thermostated at 40 ⁰C by using a ternary gradient at 0.19 mL/min flow
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rate. Eluents were (A) acetonitrile/water/formic acid (3:88.5:8.5 v/v/v), (B)
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acetonitrile/water/formic acid (50:41.5:8.5 v/v/v), and (C) methanol/water/formic
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acid (90:1.5:8.5 v/v/v). The linear solvent´s gradient was as follows: zero min, 98
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% A 2 % B and 0% C; 8 min, 98 % A 2% B and 0% C; 40 min, 70 % A 17 % B
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and 13 % C; 54 min, 50 % A 30% B and 20 % C; 54.5 min, 30 % A 40 % B and
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30 % C; 59 min, 0 % A 50 % B and 50 % C; 60 min, 0 % A 50 % B and 50 % C;
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67 min, 98 % A 2 % B and 0 % C. For identification, an Ion Trap ESI-MS/MS
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detector was used in negative ion mode, setting the following parameters: dry
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gas N2, 8 L/min; drying temperature, 325 °C; nebulizer, N2, 50 psi; scan range,
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50-1,200 m/z. Identification was based on spectroscopic data (UV-Vis and
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MS/MS) obtained from authentic standard or data previously reported in
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literature. Quantification was made using the DAD chromatograms recorded at
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280 nm (gallotannins, flavanols and flavanones) 360nm (flavonols) and 520 nm
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(anthocyanins) and calibration curves for the analysed compounds were
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prepared from pure standards, when available. Table 1 shows the UV-vis spectral
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characteristic and m/z of molecular and fragmented ions of different phenolic
205
compounds, as well as the standard employed for it quantification.
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2.6. Chemicals and solvents: catechin, epicatechin, gallocatechin and
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kaempferol-3-O-galactoside standards were purchased from Sigma Aldrich
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Chemical Co. (Tres Cantos, Madrid, Spain) and procyanidin B1, procyanidin B2,
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cyanidin-3-O-galactoside, cyanidin-3-O-glucoside, quercetin, quercetin-3-O-
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glucoside, quercetin-3-O-rutinoside, quercetin-3-O-rhamnoside and eriodictyol-
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7-O-glucoside from Extrasynthese (Genay, France). Myricetin-3-O-galactoside
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and quercetin-3-O-glucuronide were isolated from Petit Verdot red grape skins24.
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Moreover, DPPH, AAPH, Trolox, procyanidin B3, apigenin-7-O-glucoside,
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luteolin, daidzein, caffeic acid, gallic acid, coumaric acid, protocatechuic acid,
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syringic acid and vanillic acid standards (Sigma Aldrich Chemical Co., Tres
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Cantos, Madrid, Spain) where analysed in order to compare their retention time
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(Rt), ultraviolet-visible (UV-vis) and mass spectra characteristics with those of the
218
compound present in pistachio samples.
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Methanol for extraction of phenolics was acquired from Sigma-Aldrich Chemical
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Co. (Tres Cantos, Madrid, Spain). The eluent for the mobile phases were HPLC-
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MS grade acetonitrile, methanol and formic acid from (Fisher Scientific, Madrid,
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Spain). Water for mobile phase was of Milli-Q quality (Merk-Millipore, Darmstadt,
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Germany).
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2.7. Statistical analysis: Analysis of Variance (ANOVA) and Principal
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Component Analysis (PCA) were performed using XLStat 19.5 statistical
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software (Addinsoft, Paris, France). One-way ANOVA and post hoc Duncan tests
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were carried. Means were considered statistically different at p < 0.05.
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3. RESULTS AND DISCUSSION
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3.1. Determination of individual phenolic
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The identification of phenolic compounds was performed by comparison of the
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mass spectra (m/z of molecular ions and fragment ions), together with the UV-
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visible spectra and retention times with those of authentic standards, whenever
234
possible, and also with data found in bibliography. The quantification was done
235
using the standard, when available, or a representative compound of the family.
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Quantitative results of phenolic compound analysis are expressed on fresh
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weight (FW) for nuts and by-product (about 5% of moisture) and as mg/kg for oils.
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Figure 1 shows characteristic chromatograms of phenolic compounds from
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pistachio nuts at 520, 360 and 280 nm. Information about compounds
240
identification, HPLC retention time and mass and UV-Vis spectra data are
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summarised in Table 1. Numbers assigned to each compound in table 1,
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correspond with compounds numbers in figure 1 and tables 2, 3 and 4. A total of
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26 compounds (compounds 1-26 in table 1) were found in the phenolic profile of
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pistachio nuts and by-products and 25 of them were identified (three
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anthocyanins, ten flavonols, one gallotannin, nine flavanols and two flavanones).
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On the other hand, 8 different compounds (compounds 24 and 27-33 in table 1),
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all of them at very low concentration, were detected in virgin pistachio oils, but it
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was only possible to identify one of them, the flavanone eriodictyol. The same
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qualitative phenolic profile was followed by all the varieties, but significant
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quantitative differences were observed between them.
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3.2. Identification and quantification of phenolics in pistachio nuts
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Table 2, shows the phenolic composition of pistachio nuts. Differences were
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found among cultivars, being Larnaka variety that with a significantly higher
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phenolic concentration (4893 mg/kg) and appearing Avdat (4225 mg/kg) as the
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second one. Mateur and Napoletana showed an intermediate content with a
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concentration exceeding 3300 mg/kg, whilst Aegina (2240 mg/kg), Kastel (1683
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mg/kg), Kerman (1936 mg/kg) and Sirora (1980 mg/kg) belongs to the group with
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the lowest phenolic content. These results match with those reported by Ojeda-
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Amador et al.10 who found the highest total polyphenols content in Larnaka variety
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(9550 mg/kg) and the lowest one in Kastel (6168 mg/kg), expressed as gallic acid
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equivalent when measured by Folin-Ciocalteu method, among eight pistachio
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varieties.
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-
Flavanols
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The major phenolic group in pistachio nuts was the flavanols one, with a
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concentration ranging from 1522 mg/kg to 4478 mg/kg, where Kastel and Larnaka
266
presented the lowest and highest contents, respectively. This group was
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constituted by eight different compounds, contributing about 90% of the total
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amount of phenolics in the nut, with catechin, epicatechin, gallocatechin,
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procyanidin B1, procyanidin B2 and a proanthocyanidin dimer as principal
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components. Catechin, which has been determined as one of the most powerful
271
antioxidant among flavanols25, presented the highest content also in Larnaka
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cultivar with 1016 mg/kg almost seven-fold the concentration of Kastel (155
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mg/kg) and Kerman (177 mg/kg) varieties. Similar values were obtained by
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Gültekin-Özgüven et al.26 who stated a concentration of catechin between 343-
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1545 mg/kg in pistachios from Turkey. Epicatechin, has been previously found
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in pistachio skins6,13,27; in our work we found epicatechin concentrations from 42
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mg/kg (Avdat) to 630 mg/kg (Larnaka) in nuts. Similar to our findings, Gültekin-
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Özgüven et al.26, identified epicatechin in Turkish pistachio nuts with a
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concentration from 48 to 281 mg/kg, whilst Tomaino et al.13 reported a content of
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105 mg/kg in the skin of Bronte pistachios, having reported Grace et al.27 a total
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content of 151 mg/kg in pistachio skin, as well as Liu et al.6 for Kerman cultivar
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(229 mg/kg). A recent study14 stated that, in addition to variety, rootstock also
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affects epicatechin content in Kerman pistachios, ranging that from 255 mg/kg to
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426 mg/kg depending on the rootstock studied. Gallocatechin, has the major
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concentration in Napoletana cultivar with 692 mg/kg, presenting Kastel the
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smallest concentration for this compound (283 mg/kg). It is the first time that
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gallocatechin have been identified in pistachio nuts, but not in nuts; Figueroa et
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al.28 found a concentration up to 1600 mg/kg of gallocatechin in different walnut
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genotypes. Catechin gallate was also reported for the first time in pistachio as a
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minor monomeric flavanol, 31.9 mg/kg in Larnaka cultivar and 3.6 mg/kg in
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Kastel.
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Procyanidin B1 (PB1) resulted the most abundant compound in pistachio nuts,
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reaching values from 227 in Kastel to 1170 mg/kg in Larnaka. This kind of
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procyanidin has been previously described in pistachio skins, with a
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concentration of 635 mg/kg27. Procyanidin B2 (PB2) presented a concentration
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from 190 mg/kg (Aegina) to 301 mg/kg (Larnaka), being reported for the first time
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in pistachios, but stating Figueroa et al.28 a concentration from 110 mg/kg to 208
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mg/kg in walnuts cultivars. A proanthocyanidin dimer (compound 2), whose
299
mass spectra showed a molecular ion [M-H]- at m/z 593 with MS2 fragmentation
300
at m/z 423 and 305 and an UV-Vis spectra characteristic of flavanols was found
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and tentatively identified as a dimer of catechin/epicatechin (procyanidin unit) and
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gallocatechin/epigallocatechin (prodelphinidin unit). This is the first time that this
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kind of proanthocyanidin compound is reported in pistachio nuts, but a
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proanthocyanidin with the same molecular ion was found in malt29. Compound 2
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reaches its highest concentration in Mateur (558 mg/kg), Avdat (548 mg/kg) and
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Larnaka (546 mg/kg) cultivars. Kerman (202 mg/kg) and Sirora (231 mg/kg)
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varieties showed the lowest contents. Another proanthocyanidin, tentatively
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identified as a galloylated procyanidin dimer (compound 6), and not
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previously reported in pistachios, was also found, presenting the highest content
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Larnaka (146 mg/kg) and Avdat (142 mg/kg) cultivars and the lowest one in Sirora
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(37 mg/kg). Finally, a procyanidin dimer (compound 8), whose UV-Vis and
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MS/MS spectra was the same than those of PB1, PB2 and PB3 but with a
313
different retention time, appeared within a range of 15-66 mg/kg (Kastel and
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Larnaka respectively).
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Anthocyanins
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Other phenolic families such as anthocyanins were also present in pistachio
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cultivars contributing about 3.5% of the total phenolics, with Larnaka and Avdat
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as the varieties with the highest concentrations (218 mg/kg and 179 mg/kg
319
respectively) among the eight cultivars. These compounds present only in the
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skin of pistachios6,13 are responsible of the purple tonality so characteristic of this
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kind of nuts. Three compounds were identified into this group (table 2), being
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cyanidin-3-O-galactoside the major one which concentrations ranging from 44
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mg/kg in Kerman to 214 mg/kg in Larnaka. These data agree with those
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previously reported by Bellomo et al.30, who found a concentration of 145 mg/kg
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(as cyanidin-3-O-galactoside) in a turkey pistachio variety. Tomaino et al.13 also
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reported cyanidin-3-O-galactoside in a concentration of 5865 mg/kg and 35.6
327
mg/kg of cyanidin-3-O-glucoside (expressed as cyanidin-3-O-glucoside) in
328
pistachio skins from Bronte variety, having found our research group a range
329
between 1.4-8.9 mg/kg in pistachio whole nut for the last compound. Kerman
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variety presented the highest content of cyanidin-3-O-glucoside, despite being
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the variety with the lowest total anthocyanin content. Another minor anthocyanin
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was also found and identified as a peonidin-3-O-hexoside (it could be
333
galactoside or glucoside) according to its UV-Vis and MS/MS spectra. This
334
compound accounted up to 1 mg/kg in Avdat cultivar. This is not the first time that
335
peonidin derivatives have been identified in pistachio nuts, peonidin-3-O-
336
glucoside was found by Wu et al.31
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Flavonols
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Flavonols were the third group in importance, being formed by eleven
339
compounds and accounting about 2.5% of the total phenols. This family was
340
constituted with glycosides of quercetin, myricetin and kaempferol as well as free
341
quercetin. Kerman and Mateur varieties presented the highest content of this
342
phenolic group surpassing 115 mg/kg as total flavonol content. Into this family,
343
myricetin-3-O-galactoside (peak 13, figure 1B) showed the highest content
344
among flavonols in all varieties, appearing six different statistical groups with
345
Mateur (60 mg/kg) presenting the highest content and Kastel the lowest one (16
346
mg/kg). To the best of our knowledge, this is the first time this compound has
347
been identified and quantified as a component of pistachio nut. Assignment was
348
done by comparison of mass spectral data ([M-H]- at m/z 479 with MS2
349
fragmentation at m/z 317), UV-visible spectrum (maximum at 258 nm and 359
350
nm) and retention time (21.1 min) with that of the pure standard. Concerning
351
published data, Erşan et al.32 identified myricetin-3-O-galactoside in pistachio
352
hulls (exo- and mesocarp) but they did not quantify it, whilst Grace et al.27 found
353
another myricetin hexoside, myricetin-3-O-glucoside, both in skin (63 mg/kg) and
354
kernel (2 mg/kg) of pistachios. Regarding quercetin and its glycosylated
355
derivatives, the compounds that appears in a higher concentration were
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quercetin-3-O-galactoside (4.9 mg/kg, Aegina 15.1 mg/kg, Avdat), quercetin-
357
3-O-glucoside (4.6 mg/kg, Aegina and Napoletana
358
quercetin-3-O-glucuronide (2.8 mg/kg, Aegina – 8.2 mg/kg Kerman) and
359
quercetin-3-O-rhamnoside (2.6 mg/kg, Napoletana – 17.6 mg/kg Kerman);
360
whilst quercetin-3-O-pentoside,
361
rhamnosil-glucoside-5-glucoside and quercetin aglycone contribute with
362
about 2 mg/kg each one to the total content of phenolics. Barreca et al.33 and
363
Erşan et al.32 also identified these compounds (with the exception of quercetin-3-
364
O-rhamnoside and quercetin-3-O-rhamnosil-glucoside-5-glucoside) in extracts of
365
pistachio hull, and Grace et al.27 found quercetin-3-O-galactoside, quercetin-3-O-
366
glucoside, quercetin-3-O-rutinoside and quercetin aglycone in pistachio nuts but
367
this is the first time that quercetin-3-O-glucuronide, quercetin-3-O-pentoside and
368
quercetin-3-O-rhamnoside have been identified (tentatively identification for
369
quercetin-3-O-pentoside, according to their UV-Vis and MS/MS spectra) in
370
pistachio nuts. Moreover, compound 22 (table 1, figure 1B) presented the same
371
UV-Vis and MS/MS spectra than the pure standards of kampferol-3-O-
372
galactoside and kaempferol-3-O-glucoside, however their retention times differed
373
to that of compound 22 so it cannot be assigned; therefore we tentatively
374
identified compound 22 as a kaempferol-hexoside (as previously tentatively
375
identified by Erşan et al.32 in pistachio hulls) with a range of concentration
376
between 4.8 mg/kg (Mateur) and 40.0 mg/kg (Napoletana). Some authors have
377
previously reported the presence of kaempferol aglycone13,34 in pistachios and
378
very recently Noguera-Artiaga et al.14 reported for the first time the presence of a
379
kaempferol glycoside in pistachios (Kerman cultivar, 17 mg/kg) which they
380
assigned as kaempferol-3-O-glucoside. However, our results using pure
11.9 mg/kg, Kerman),
quercetin-3-O-rutinoside, quercetin-3-O-
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381
standards (kaempferol-3-O-glucoside and kaempferol-3-O-galactoside) do not
382
support the identity they assigned to this flavanol14. Finally, a compound
383
(compound 26, table 1, Rt = 28.6 min) with [M-H]- at m/z 547, fragment ion at m/z
384
385 and a UV-Vis spectra similar to that of flavonols (maximum at 257 nm and
385
359 nm) has been found, however its identification was not possible and it
386
appears in table 2 as Rt 28.6. This compound presents a very similar
387
concentration for all varieties (about 12 mg/kg) except for Sirora, which contained
388
an amount of 20.5 mg/kg and formed a statistically-separated group with the
389
maximum content.
390
-
Gallotannins
391
Pentagalloyl glucose was the only component of the gallotannis family
392
tentatively identified in pistachio nuts according to their UV-Vis and MS/MS
393
spectra. Its concentration ranged from 4 mg/kg in Kastel to 46 mg/kg in Avdat
394
cultivar. Erşan et al.32 also identified a pentagalloyl glucose (penta-O-galloyl-β-D-
395
glucose) in pistachio hulls but this is the first time that this gallotannin has been
396
found in pistachio nuts.
397
-
Flavanones
398
To conclude, pistachio nuts also contain compounds from flavanone´s family,
399
representing from 0.7% to 2.1% of the total amount of phenolics. They were
400
represented by two compounds, eriodictyol and eriodictyol-7-O-glucoside,
401
being the last one that presenting the higher concentration with Mateur (65.2
402
mg/kg) and Kastel (8.2 mg/kg) as the varieties with the maximum and minimum
403
values. Comparing with bibliography, very close values were published by
404
Rodríguez-Bencomo et al.35 with 22 mg/kg of eriodictyol and 41 mg/kg of
405
eriodictyol-7-O-glucoside in pistachios of Uzun cultivar (Turkey). Grace et al.27
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only identified eriodictyol-7-O-glucoside in pistachios with a concentration of 59
407
mg/kg in skin and 4 mg/kg kernel, whilst Ballistreri et al.12 only identified
408
eriodictyol in pistachio nuts with a concentration of 21 mg/kg. Tomaino et al.13
409
also identified both compounds in the skin (63 mg/kg, eriodictyol; 366 mg/kg,
410
eriodictyol-7-O-glucoside) and kernel (9 mg/kg, eriodictyol; 32 mg/kg, eriodictyol-
411
7-O-glucoside) of pistachio from Bronte variety. Martorana et al.34 found both
412
compounds, eriodictyol and eriodictyol-7-O-glucoside, in the skin (245 mg/kg and
413
1121 mg/kg, respectively) and kernel (112 mg/kg and 275 mg/kg, respectively) of
414
pistachios from Bronte variety, being these concentrations higher than those
415
reported in the present work and the other authors.
416
Published literature have reported the presence of different phenolic acids in
417
pistachio nuts26 such as syringic, gallic, proto-catechuic, caffeic, ferulic, o-
418
coumaric and p-coumaric acids. In this sense, pure standards of these
419
compounds were injected into our HPLC-DAD-ESI-MS/MS system and no mass
420
spectra/fragmentation, retention time neither UV-vis spectra coincided with any
421
of the signals of our pistachio samples.
422
3.3. Individual phenolic compounds in residual cakes
423
The same 26 phenolic compounds found in pistachio nuts appeared in the
424
resulting residual cake, but in this case with a higher concentration. This means
425
that the extrusion process doesn´t change the natural profile of phenolic
426
compounds presented in the raw material. Furthermore, their concentrations
427
were increased in the by-product due to oily phase removal (~20% oil in residual
428
cake) and the low solubility of the phenolic compounds in the extracted oil. This
429
fact makes it possible to think in novel and potential applications of the residual
430
cakes as functional ingredients and rich sources of bioactive compounds. In this
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431
sense, flavanols were the major phenolic compounds determined in by-products
432
and all of them were found in higher concentration than in the nut. This group
433
represents from 88 to 92% of the total phenolic compounds content, with
434
catechin (215 mg/kg, Kastel; 1580 mg/kg, Larnaka) and procyanidin B1 (402
435
mg/kg, Kastel; 1945 mg/kg, Larnaka) as the compounds with the highest
436
concentrations, depending on the variety. Moreover, epicatechin (229 mg/kg,
437
Mateur; 823 mg/kg, Larnaka), gallocatechin (641 mg/kg, Kerman; 1099 mg/kg,
438
Aegina) and proanthocyanidin dimer (compound 2) (312 mg/kg, Kerman; 845
439
mg/kg, Larnaka) were also major compounds in these by-products. Whereas, the
440
galloylated procyanidin dimer (compound 6) and the procyanidin dimer
441
(compound 8) resulted as minor flavanols in the residual cakes with a range
442
between 71 mg/kg, Napoletana
268 mg/kg, Mateur; and 19 mg/kg, Napoletana
443
120 mg/kg, Mateur; respectively. Finally, catechin gallate was the flavanol with
444
the smallest concentration, from 9 mg/kg in Napoletana to 65 mg/kg in Larnaka.
445
Some differences among varieties are shown (tab. 3), for example Aegina (1099
446
mg/kg), Kastel (678 mg/kg), Kerman (641 mg/kg), Napoletana (788 mg/kg) and
447
Sirora (780 mg/kg) contained gallocatechin as principal phenolic. However,
448
Avdat, Larnaka and Mateur contained procyanidin B1 as principal component
449
with a concentration from 1390 mg/kg (Avdat) to 1945 mg/kg (Larnaka).
450
Moreover, epicatechin (4% Mateur, 14% Napoletana) and proanthocyanidin
451
dimer (10% Kerman, 14% Mateur) also represented a very important percentage
452
in residual cakes. The comparison of flavanols levels revealed four statistical
453
different groups among cultivars, again with Larnaka as the variety with the
454
highest content (7089 mg/kg). Comparing with bibliography, just one study
455
related to phenolic compounds in pistachio residual cakes (screw press
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extraction) from Kerman variety have been published; in that case three flavanols
457
were identified with catechin as the principal component (65.5 mg/kg) followed
458
by procyanidin dimer (15 mg/kg) and epicatechin (7.7 mg/kg)18. These results
459
partially agree with our findings, although they reported a much lower
460
concentration than our research.
461
Anthocyanins were found as the second major group of flavonoids in residual
462
cakes, with cyanidin-3-O-galactoside as the mayor compound. Larnaka cakes
463
showed the highest concentrations of this compound (291 mg/kg) and Kastel and
464
Kerman the lowest (72 and 75 mg/kg). The other two anthocyanins were found in
465
minor amounts. Cyanidin-3-O-glucoside ranged from 1.9 to 4.9 mg/kg in all
466
varieties except for Kerman, which overpassed 12.8 mg/kg, while peonidin-3-O-
467
hexoside showed the lowest concentration in all varieties. Martínez et al.18 also
468
identified cyanidin-3-O-galactoside (21 mg/kg) and cyanidin-3-O-glucoside (0.9
469
mg/kg) as components of pistachio flours obtained after oil extraction although
470
the contents were lower than that obtained in our research.
471
Among flavonols, myricetin-3-O-galactoside was the most abundant in all
472
samples, ranging from 38 mg/kg for Aegina cultivar to 98 mg/kg for Mateur. Other
473
flavonols like quercetin-3-O-galactoside and quercetin-3-O-glucoside were
474
present in halfway concentration, between 6-20 mg/kg. Finally, kaempferol-
475
hexoside, quercetin aglycone and the rest of glycosides of quercetin were
476
minor flavonol in most cakes. The total amount of flavonols contained in this
477
matrix was between 2.4% (Avdat) and 5.7% (Kerman) of the total phenolic
478
compounds. Martinez et al.18 reported free quercetin and myricetin as well as
479
quercetin-3-O-glucoside and a quercetin-3-O-hexoside in the by-products from
480
Kerman variety but in a concentration smaller than 5 mg/kg for every compound.
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481
Pentagalloyl glucose, the only gallotannin found, increased its concentration in
482
the residual cake respect to nut, as the other phenolic compounds. Pentagalloyl
483
glucose concentration was from 22 mg/kg to 96 mg/kg in Kerman and Larnaka
484
varieties, respectively and four different statistical groups appeared. Martínez et
485
al.18 found gallic acid in the residual cake but not a pentagalloyl glucose.
486
Eriodictyol-7-O-glucoside with a concentration ranging from 16 mg/kg (Kastel)
487
to 124 mg/kg (Larnaka) and eriodictyol from 6.9 mg/kg (Kerman) to 20.0 mg/kg
488
(Aegina) were the only flavanones found. Previous studies also found similar
489
contents of eriodictyol (11.3 mg/kg) in by-products from Kerman variety18, but the
490
level eriodictyol hexosides found in that study (0.80 mg/kg Approx.) were much
491
lower than the contents of eriodictyol-7-O-glucoside determined among the eight
492
varieties of our study.
493
To conclude, the total concentration of phenolic compounds in pistachio by-
494
products goes from 7774 mg/kg for Larnaka to 3217 mg/kg for Kerman varieties
495
which corresponded to the statistical group with the lowest and highest content
496
respectively.
497
3.4. Individual phenolic compounds in virgin oils
498
Due to the polarity characteristics of phenolic compound their transference from
499
fruit to oil during the extraction process was very low. Concentrations below 0.4
500
mg/kg were found in every sample of virgin oil facing contents between 4507 and
501
1507 mg/kg in nuts. Furthermore, pistachio nuts which presented the highest
502
content of phenolics did not lead to the oils with the highest concentration. Due
503
to their low concentration, phenolic compounds have apparently no effect on the
504
sensory characteristics of these pistachio oils; and the sensory attributes bitter
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505
and/or astringent, commonly associated to flavan-3-ols36, the major phenolic
506
compounds found in pistachio nuts, were not detected, resulting “sweet” virgin
507
pistachio oils as described by trained assessors10.
508
Eight different peaks were detected in virgin pistachio oil chromatograms
509
acquired at 280 nm, but only one of them was identified as a phenolic compound,
510
eriodictyol, and the other seven remain unknown (Table 4). The unknown
511
family presented the highest concentration with a percentage accounting about
512
98 % depending on the variety, eriodictyol was found in very low concentration
513
(from 0.01 to 0.06 mg/kg). Saber-Tehrani et al.37 and Sonmezdag et al.38 studied
514
the phenolic composition of virgin pistachio oils and also found eriodictyol among
515
other compounds such as gallic acid, protocatechuic acid, catechin and rutin, all
516
of them in a very low concentration. We could not identify those compounds in
517
our oils despite having the pure standards of all of them.
518
On the other hand, tocopherols - a lipophilic phenolic compound group - have
519
been reported to be present in this virgin pistachio oils, being γ-tocopherol the
520
main homolog with concentrations ranging between 548 mg/kg (Larnaka) and
521
719 mg/kg (Kastel), but also with the presence of α- and β-tocopherols and δ-
522
and γ-tocotrienols (1.2–2.8% each of the total amount)10.
523
3.5. Antioxidant activity of pistachio nuts, residual cakes and virgin oils
524
from different pistachio varieties
525
Figure 2.a., shows the antioxidant activity of pistachio nuts and by-products from
526
different varieties, evaluated by the DPPH and ORAC methods. Both methods
527
have different basis, while DPPH test measures the capacity of the compound to
528
scavenge the stable radical 2,2-Diphenyl-1-picrylhydrazyl by donating a
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Page 22 of 41
529
hydrogen atom or an electron, ORAC method evaluates the capacity of
530
compounds to inhibit peroxylradical-induced oxidation of fluorescein initiated by
531
thermal
532
(AAPH). This difference in the basis of these methods led to changes in the
533
relative order of the samples antioxidant activity regarding to the method used.
534
Among pistachio nuts, Larnaka presented the highest Trolox Equivalent
535
Antioxidant Capacity (TEAC) both DPPH (35 mmol TE/kg) and ORAC (330 mmol
536
TE/kg), belonging to a different statistical group. Moreover, Mateur and Avdat
537
presented both a TEAC of 28 mmol TE/kg (DPPH) and 282 mmol TE/kg and 168
538
mmol TE/kg (ORAC) respectively, being the cultivars with the second highest
539
antioxidant activity. Kastel and Kerman were the varieties with the smallest TEAC
540
values with 13 mmol TE/kg and 10 mmol TE/kg (DPPH) and 89 mmol TE/kg and
541
61 mmol TE/kg (ORAC) respectively. These results partially match with those
542
obtained from the total phenolic content when analysed by HPLC, being Larnaka,
543
Mateur and Avdat the varieties with a highest concentration and Kastel and
544
Kerman the ones with the smallest content. These results were similar to those
545
obtained by Rodríguez-Bencomo et al.35, who studied the antioxidant activity, by
546
DPPH method, of a Turkish pistachio cultivar (Uzun) which resulted in 8 mmol
547
TE/kg. Moreover, Wu et al.31 developed a database regarding ORAC in foods,
548
obtaining a concentration of 76 mmol TE/kg for pistachio nuts, with results very
549
close to our results for Kastel (61 mmol TE/kg) and Kerman (89 mmol TE/kg)
550
cultivars.
551
Regarding by-products, the concentration of phenolic compounds respect their
552
corresponding nuts, due to the extraction of the oil, observed previously have a
553
reflection in their antioxidant activity values. Varieties followed the same trend
decomposition
of
2,2’-azobis(2-amidino-propane)
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Page 23 of 41
Journal of Agricultural and Food Chemistry
554
than nuts, being Larnaka the cultivar with the highest TEAC. However, while
555
according to the DPPH test Larnaka showed higher antioxidant activity than
556
Mateur, in the ORAC test no significant differences were found between these
557
two cultivars. Kerman presented the lowest antioxidant activity with 19 mmol
558
TE/kg and 156 mmol TE/kg for DPPH and ORAC respectively.
559
Finally, all virgin pistachio oils presented a very low TEAC, less than 0.1 mmol
560
TE/kg for DPPH and 1 mmol TE/kg for ORAC, being Kerman that presenting the
561
highest TEAC in both assays with 0.1 mmol TE/kg (DPPH) and 0.8 mmol TE/kg
562
(ORAC).
563
3.6. PCA biplot of phenolic compounds in pistachio nuts from different
564
varieties
565
Throughout all the results and discussion section of this work, it has been shown
566
that genetic differences among eight Pistacia vera L. cultivars grown exactly
567
under the same agronomical and climatic conditions led to statistically significant
568
differences in phenolic compounds content and antioxidant activity. Literature
569
regarding phenolic composition of most of the cultivars presented in this work is
570
scarce and most of available information correspond to Kerman and Napoletana
571
(also known as Bianca)12,14,30. Some studies have stated the differentiation of
572
many pistachio cultivars through DNA analysis techniques such as microsatellite
573
markers; however, as for phenolic compounds, we have not found any
574
information about many of the varieties included on this article, being Kerman,
575
Mateur, Aegina, and Sirora those of our cultivars found in literature39-41..
576
Principal Component Analysis (PCA) of the phenolic composition depicted in
577
Figure 3 explained 62.39 % of the observed variance.
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Journal of Agricultural and Food Chemistry
Page 24 of 41
578
Attending to the principal component 1 (F1, 39.70 %), samples are divided in two
579
groups. Avdat, Larnaka and Mateur varieties appeared in the positive part of the
580
F1, which is mainly related to pentagalloyl glucose (factor loading: 0.969); the
581
flavanols procyanidin B1 (0.953), catechin (0.924), catechin gallate (0.908) and
582
procyanidin dimer (0.848), the flavanone eriodictyol-7-O-glucoside (0.831) and
583
the anthocyanin cyanidin-3-O-galactoside (0.889). The rest of the samples –
584
Aegina, Kastel, Kerman, Napoletana and Sirora – belongs to the negative part of
585
the F1 which is related to the quercetin derivative compounds but with
586
kaempferol-hexoside as the component with the highest negative contribution (-
587
0.722).
588
Regarding the second component (F2, 22.69 %), Kerman was clearly separated
589
in the uppers part of the positive side of the PCA graphic and presented the
590
highest differences with Aegina and Napoletana varieties, appearing these ones
591
in the lowest part of the graphic. Kastel, Sirora, Mateur, Avdat and Larnaka had
592
values close to zero for F2. This second component is positively related with
593
quercetin-3-O-rhamnoside
594
quercetin-3-O-glucoside (0.854) and negative connected with quercetin-3-O-
595
pentoside (-0.817) and eriodictyol (-0.787).
596
Considering both components together, pistachio varieties were clearly divided
597
into four groups according to its phenolic composition. Kerman in the left upper
598
side of the graph, Kastel and Sirora in the middle left part, Mateur, Avdat and
599
Larnaka in the middle right part, and finally Aegina and Napoletana in the bottom
600
left side. Since phenolic compounds are related with sensory characteristics of
601
food, these qualitative and quantitative differences in the phenolic compounds
602
profile of nuts, which were also observable in by products, could be responsible
(0.847),
cyanidin-3-O-glucoside
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and
Page 25 of 41
Journal of Agricultural and Food Chemistry
603
of a part of the differences in the sensorial properties found among pistachio
604
varieties42. Cultivar groups found in our PCA study did not agree with those
605
expected from data regarding genetic similarity of cultivars. According to the
606
results of microsatellites presented by Fares et al.40, Kerman and Mateur cultivars
607
are very close, but according to the phenolic composition found in our work they
608
have a clearly different profile. On the other hand, the dendogram presented by
609
Motalebipour et al.41, positioned Sirora and Kerman as close cultivars, while
610
Aegina showed some differences. However, in PCA analysis (figure 3), Sirora is
611
closer to Aegina than to Kerman, which seems that phenolic compositional
612
differences must be due to genetic differences located in DNA regions different
613
from those corresponding to the SSR markers used by Motalebipour et al.41 and
614
Fares et al.40
615
To conclude, 25 phenolic compounds were identified and quantified in pistachio
616
nuts and by-products, being reported for the first time five flavonols (myricetin-3-
617
O-galactoside, quercetin-3-O-glucuronide, quercetin-3-O-pentoside, quercetin-3-
618
O-rhamnoside and kaempferol-hexoside), six flavanols (procyanidin B2,
619
gallocatechin,
620
procyanidin dimer and catechin gallate) and one gallotannin (pentagalloyl
621
glucose). In this sense, flavanols were the most abundant phenolic compounds,
622
accounting about 90% of the total phenolics and procyanidin B1 and
623
gallocatechin resulted as the major phenolic components depending on the
624
variety. Moreover, other families such as anthocyanins, flavonols, flavanones and
625
gallotannins were found in all cultivars. To the best of our knowledge, this is the
626
most comprehensive study of phenolics in pistachio nuts and the first report
627
regarding phenolic profile characterization of different pistachio cultivars (growing
proanthocyanidin
dimer,
procyanidin
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dimer,
galloylated
Journal of Agricultural and Food Chemistry
628
under the same conditions), their residual cakes and virgin pistachio oils. The
629
high phenolic compounds and reduced fat contents of these residual cakes open
630
new ways to their use as healthy ingredients by the food industry as snacks or in
631
other applications which should be explored.
632 633
Acknowledgement
634
The authors acknowledge their indebtedness to the “Centro de Mejora Agraria,
635
El Chaparrillo-IRIAF” for providing the pistachio samples used in this research
636
work.
637
Founding sources
638
This research project was supported by the Junta de Comunidades de Castilla-
639
La Mancha and the European Regional Development Fund (FEDER; ref. POII-
640
2014-003-P).
641 642 643 644 645 646 647 648 649 650 651 652 653
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FIGURES AND TABLES CAPTIONS
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Table 1.- Chromatographic, UV-Vis and mass (negative ionization mode) spectral characteristics of phenolic compounds found in this study.
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RT (retention time)
793 794 795 796 797 798
Table 2. Content of individual phenolic compounds from the groups of anthocyanins, flavanols, flavanones, flavonols and gallotannins (mg/kg, FW) in pistachio nuts from different cultivars. Values in the same row with different lower-case letters (a – f) are significantly different at p