Journal of Applied Botany and Food Quality 86, 1 - 10 (2013), DOI:10.5073/JABFQ.2013.086.001

Dipartimento di Scienze Agrarie, Forestali e Alimentari, Università degli Studi di Torino, Grugliasco (TO), Italy

Currants and strawberries as bioactive compound sources:
determination of antioxidant profiles with hplC-DAD/ms

D. Donno*, m. Cavanna, G.l. Beccaro, m.G. mellano, D. Torello marinoni, A.K. Cerutti, G. Bounous
(Received January 18, 2013)

* Corresponding author

summary
Among plant foods, berry fruit shows a high antioxidant capacity.
Medical research has pointed out the medicinal properties of certain
pigmented polyphenols, such as flavonoids, anthocyanins, tannins
and other phytochemicals, which are mainly found in the skin and
seeds of the berries. The aim of this work was to contribute to the
study of the nutraceutical features of some berry fruit (currants,
gooseberries and strawberries). The different antioxidant compound
contents of the fresh fruit of different cultivars and selections of
Ribes spp. and Fragaria x ananassa Duch have been analyzed.
The fruit of 29 cultivars from 3 different species of Ribes spp. and
5 strawberry cultivars have been analysed by High Performance
Liquid Chromatography coupled to a UV/Vis detector and a
mass detector (MS) to identify and quantify the main antioxidant
compounds.
As far as the Ribes spp. cultivars are concerned, the presence of a
high content of phenolic compounds has been confirmed, and they
represent therefore an important source of antioxidant compounds.
Moreover, the results have shown that the considered cultivars and
selections of strawberries are good sources of bioactive compounds,
especially phenolic substances. The results of this study could con-
tribute to offer new insights into the nutraceutical aspects of the
considered berry fruit species.

Introduction
The word “berry” has two meanings: one based on a botanical
definition, the other on the common commercial identification.
True (botanical) berries are fleshy fruit with a cartilaginous endo-
carp full of seeds. Black currants, red currants and gooseberries
are true berries because they are many-seeded epigynous berries
(WestWood, 1993). Other berries are not real berries according
to the scientific definition. Blueberries, instead, can be defined as a
fake epigynous berry. Strawberries are not berry fruit but either are
multiple fruits developed from a dialycarpous ovary (on aggregate
of drupes: Rubus, on aggregate of achenes: Fragaria) (spichiger
et al., 2002). The common term “berry fruit” includes different
fruits, such as strawberry (Fragaria spp.), blueberry (Vaccinium
spp.), currant and gooseberry (Ribes spp.), raspberry and blackberry
(Rubus spp.). “Berry fruit”, “soft fruit” and “small fruit” are
synonymous terms for the above mentioned species, and they are
used indifferently. In this work, the term “berry fruit” is used to
indicate all the analyzed species.
It is well known that a healthy diet includes the consumption of fruit
and vegetables. Many medical and epidemiological studies have
shown an inverse relationship between fruit consumption and the
incidence of coronary and heart diseases, as well as certain cancers
(rice-evans et al., 1997; BuB et al., 2003; vanamala et al., 2006).
Among plant foods, berry fruits show a high antioxidant capacity.
Medical research has pointed out the medicinal properties of certain
pigmented polyphenols, such as flavonoids, anthocyanins, and
tannins and other phytochemicals, mainly located in the skins and
seeds of berries. The nutritional content and antioxidant activity are

used to distinguish several berries in a new category of functional
foods called “superfruits”, a rapidly-growing multi-billion dollar
industry that began in 2005 and which has been identified by
DataMonitor as one of the top 10 food categories for growth in 2008
(FOOD U.S.A. navigator, 2007).
Phenolic compounds are abundant in highly colored berry fruit, and
due to their popularity and consumption, these berry fruits serve as
one of the most important dietary sources of phenolics (KahKonen
et al., 2001). Berry fruits are reported to contain a wide variety of
phenolics, including hydroxybenzoic and hydroxycinnamic acid
derivatives (phenolic acids), anthocyanins, flavonols, flavanols,
condensed tannins (proanthocyanidins) and hydrolyzable tannins
(machiex et al., 1990). The chemical characteristics, that are, nature,
size, structure, solubility, degree and position of glycosylation, the
type of esterification or polymerization and conjugation of phenolics
with other compounds can influence their bioavailability, absorption,
distribution, metabolism and excretion in humans (aherne and
o’Brien, 2002; hollmann, 2001). Phenolic components, as
mentioned above, can range from simple molecules, such as
phenolic acids, to highly polymerized compounds, such as tannins.
The phenolic compounds found in berries can be divided into
two principal categories: flavonoid compounds and non-flavonoid
compounds, which include the so called phenolic acids, tannins and
coumarins.
Vitamin C is also an important antioxidant berry fruit constituent.
Vitamin C is a highly effective antioxidant in humans, which act
by lowering oxidative stress, a substrate for ascorbate peroxidase. It
is also an enzyme cofactor for the biosynthesis of many important
biochemicals, and it acts as an electron donor for eight different
enzymes. The term vitamin C is usually used as the generic de-
scriptor of all the components of fruit that exhibit the biological
activity of ascorbic acid. In fruit, vitamin C is assumed to be the
sum of the ascorbic acid (AA) and dehydroascorbic acid (DHAA)
contents. These two substances are readily oxidized, especially
when exposed to elevated temperatures, some divalent cations (e.g.
copper and iron), oxygen, alkaline pH, light or degradative enzymes.
Ascorbic acid is a necessary human nutrient, and its biological
functions are centered on its antioxidant properties in the biological
system. Furthermore, it prevents common degenerative processes
(smirnoff et al., 2000). Ascorbic acid is the principal biologically
active form, but dehydroascorbic acid also exhibits biological
activity, since it can easily be converted into ascorbic acid in the
human body. Therefore, it is important to measure both ascorbic and
dehydroascorbic acid.
The aim of this work was to contribute to the study of the
nutraceutical features of some berry fruit (currants, gooseberries and
strawberries), by analyzing the fresh fruit of different cultivars and
selections of Ribes spp. and Fragaria x ananassa Duch.

Materials and methods
plant material
Currant and gooseberry samples of 29 cultivars from three different
species of Ribes spp. (Tab. 1a) have been harvested at commercial

2 D. Donno, M. Cavanna, G.L. Beccaro, M.G. Mellano, D. Torello Marinoni, A.K. Cerutti, G. Bounous

ripeness, according to the maturity stage of the cultivars. All
the cultivars were collected from a germplasm repository in the
Piedmont Region, Italy. A protocol usually applied for raspberries
(Zafrilla et al., 2001) and strawberries (allende et al., 2007) has
been modified for the currants and gooseberries.
Five strawberry genotypes (Fragaria x ananassa Duch.) (Tab. 1b)
were collected from a greenhouse on a Spanish farm (Huelva,
Andalusia, Spain) under Mediterranean climatic conditions.
This fruit was harvested at the commercial maturity stage. Three
replications of 10 g of fruit were selected and frozen for each
genotype in liquid nitrogen and kept at -80 °C until analyzed, while
other three replications of 10 g of fruit where immediately analyzed
for their vitamin C content.

Extraction of phenolic compounds
The phenolic compounds were extracted as described by allende
et al. (2007). A lyophilized powder sample (0.77 g) of each sample
was homogenized with 25 mL of an extraction solution (acetone/
water/acetic acid, 70:29.5:0.5, v/v/v) using an Ultra Turrax (Ika,
Staufen, Germany) for 1 min on ice, and this was followed by
sonication in a bath-type ultrasonic cleaner (5510E-MTH, Branson
Ultrasonic Corporation, U.S.A.) for 15 min. The homogenates were
then centrifuged at 3,200 rpm for 10 min in a JP Selecta Centronic
centrifuge. The acetone was evaporated at 35 °C using a rotary
evaporator under vacuum. After evaporation of the acetone, the
residue was flushed through a Sep-Pak C-18 cartridge, previously
activated with methanol, and then with water and air. The phenolic
compounds were absorbed onto the column, while sugars, acids and
other water-soluble compounds were eluted with 10 mL of water. The
phenolic compounds were then recovered with approximately 8 mL
of methanol. The methanol was evaporated at 35 °C under vacuum

and recovered in 1 mL of extraction solution, filtered through a
0.45 µm Nylon filter (Millex HV13, Millipore, Bedford, MA) and
directly analyzed by High Performance Liquid Chromatography
(HPLC).

Analysis of phenolic compounds using reverse-phase HPLC with
Diode Array Detector (DAD) and Tandem mass spectrometry
(ms-ms)
Fifty µL samples of the extracts were analyzed using an HPLC
system (Merck Hitachi, Tokyo, Japan) equipped with a model
L 7100 pump and a model L-7455 photodiode array UV/Vis detector.
The samples were injected using an autosampler (model L-7200).
Compound separations were achieved on a 250 mm x 4 mm i.d.,
5 µm reversed phase LiChrocart C18 column (Merck, Darmstadt,
Germany) with water/formic acid (H2O:CH3COOH) (95:5, v/v) (A)
and methanol (B) used as mobile phases. The linear gradient started
with 3 % B, at 5 min 5 % B, at 10 min 8 % B, at 15 min 13 % B,
at 19 min 15 % B, at 47 min 40 % B, at 64 min 65 % B, at 66 min
98 % B, at 69 min 98 % B and at 70 min 3 % B. The flow rate was
1 mL/min, and chromatograms were recorded at 280, 320, 360 and
510 nm. Anthocyanins were quantified through comparisons with an
external standard of cyanidin 3-glucoside at 510 nm, flavonols as
quercetin 3-rutinoside at 360 nm, hydroxycinnamic acid derivatives
as chlorogenic acid at 320 nm, and flavan-3-ols as catechins at
280 nm (all these markers were from Sigma, St. Louis, MO). The
results were expressed as mg per 100 g fresh weight. The phenolics
identification was carried out considering their UV spectra,
molecular weights, and their MS-MS fragments.
Electrospray mass spectrometric analyses were performed using
an HPLC system equipped with a DAD detector and mass detector
in series consisting of a G1312A binary pump, a G1313A auto-
sampler, a G1322A degasser, a G1315B photodiode array detector,
and an ion trap mass spectrometer equipped with electrospray
ionization (ESI), operating in the negative ion mode, and controlled
by software (v.4.0.25) from Agilent Technologies (Waldbronn,
Germany). The heated capillary and the voltage were maintained
at 350 °C and 4 kV, respectively. Mass scan (MS) and daughter
(MS-MS) spectra were measured from m/z 100 to ~1500. Collision-
induced fragmentation experiments were performed in the ion trap
using helium as the collision gas, and the collision energy was set
at 50 %. The mass spectrometry data were acquired in the negative
mode for all of the phenolic compounds.
The phenolic compounds in the fruit extracts were identified by their

Tab. 1a: Ribes spp. cultivars

Ribes spp. cultivars

Ribes nigrum L. (black currant) Ribes rubrum L. (red currant) Ribes grossularia L. (goosberry) Ribes x nidigrolaria (hybrids)

Andega Augustus Rokula Jogranda
Ben Lomond Blanka field A Jostine
Ben more Erden
Ben sarek Gloire de Sablons
Black Down Jonker Van Tets
Black reward Junifer
Burga Red poll
Geant de Boskoop Red start
Invigo Red win
Noir de Bourgogne Roodneus
Royal de Naples Rotet
Tenah Rovada field A
Wellington Werdavia

Tab. 1b: Fragaria x ananassa L. cultivars and selections

Fragaria x ananassa L.

163M88
148M6
150M61
29K55
160M77

Nutraceutical profiles of currants and strawberries 3

UV spectra, which was recorded by means of a diode-array detector
and HPLC-MS, and, wherever possible, through chromatographic
comparisons with authentic pure standards.

Analysis of proanthocyanidins: phloroglucinol protocol
The analysis of proanthocyanidins was performed as described by
Kennedy et al. (2001). The proanthocyanidins (PAs) of 11 samples
belonging to genus Ribes were made to react with a solution of
0.1 N HCl in MeOH, containing 5 g/L phloroglucinol and 10 g/L
ascorbic acid at 50 °C for 10 min, and then combined with 1.2 mL of
aqueous sodium acetate to stop the reaction.
The phloroglucinol adducts were analyzed by means of reversed-
phase HPLC. The used column was a LiChrocart C18 (particle
size 5µm, 250 mm x 4 mm i.d., Merck, Darmstadt, Germany),
protected by a guard column containing the same material. The
method utilized a binary gradient with a mobile phase containing
1 % v/v aqueous acetic acid (mobile phase A) and methanol (mobile
phase B). The eluting peaks were monitored at 280 nm. The elution
conditions were 1.0 mL/min; 5 % B for 10 min, a linear gradient
from 5 to 20 % B for 20 min, a linear gradient from 20 to 40 % B
for 25 min. Then the column was washed with 90 % B for 10 min
and reequilibrated with 5 % B for 5 min before the next injection.
The proanthocyanidin cleavage products were estimated using their
response factors in order to calculate the apparent mean degree
of polymerization (mDP), the sum of all subunits (flavan-3-ol
monomers and phloroglucinol adduct, in moles) was divided by the
sum of all flavan-3-ol monomers (in moles).

Extraction and analysis of vitamin C
The ascorbic acid (AA) and dehydroascorbic acid (DHAA) contents
were determined according to Zapata and dufour (1992), with
some modifications. The analysis was just carried out with fresh
strawberry samples.
10 g of fresh fruit was homogenized for 30 s in 10 mL of the
extraction solution (0.1 M citric acid, 2 mM ethylene diamine
tetraacetic acid (EDTA) disodium salt and 4 mM sodium fluoride
in methanol – water 5:95, v/v) on a Ultraturrax T-25 (Jauke and
Kundel IKA, Dabortechnik, Staufen, Germany). The homogenates
were then filtered through cheesecloth, centrifuged at 10,500 rpm
for 5 min at 2-5 °C, filtered through an activated C18 Sep-Pak cart-
ridge (Waters, Milford, MA) and finally filtered through a 0.45 µm
filter. Then, 250 µL of 1,2-phenylenediamine dihydrochloride
(OPDA) solution (35 mg/100 mL) was added to 750 µL of extract
for dehydroascorbic acid derivatization in the fluorophore 3-(1,2-
dihydroxyethyl)furo[3,4-b]quinoxaline-1-one (DFQ). After 37 min
in darkness, the samples were analysed by means of HPLC.
The ascorbic and dehydroascorbic acids were evaluated using an
HPLC system (Merk Hitachi, Tokio, Japan), equipped with an L-
6000 pump coupled to a D-2500 variable-wave-length UV detector.
20 μL samples were injected into a reversed-phased Kromasil 100
C18 column (250 mm × 4 mm i.d., 5 µm particle size; Tecnokroma,
Barcelona, Spain) with an ODS C18 guard precolumn. The mobile
phase was methanol/water (5/95, v/v), 5 mM cetrimide and 50 mM
KH2PO4 at pH 4.5. The flow rate was kept at 0.9 mL/min. The
detector wavelength was initially set at 348 nm, and after being
DFQ eluted, it was manually shifted to 261 nm for ascorbic acid
detection. The ascorbic and dehydroascorbic acids were identified
and quantified through a comparison with the pattern areas from AA
and DHAA. The AA and DHAA standards were purchased from
Sigma-Aldrich (Steinheim, Germany). The vitamin C content was
calculated by adding the ascorbic and dehydroascorbic acid contents,
and the results were expressed as mg per 100 g fresh weight.

statistical analysis
All the data were subjected to one-way analysis of variance (ANOVA)
to compare the means, using SPSS 18.0 software (Chicago, IL), and
significant differences between samples were calculated according
to the HDS Tukey multiple range test at p<0.05 (probability level).
The data shown are the mean values (n=3) ± standard deviation.

Results
Characterization and quantification of the phenolic com-
pounds
The combination of the data with mass spectra (MS) data allowed
a tentative identification to be made of the conjugated forms, as
obtained in previous studies (he, 2000; schieBer et al., 2001).

strawberries
Fifteen compounds were identified and quantified in the HPLC-DAD
chromatograms of the strawberry selections. The molecules were
classified as different phenolic compounds (Tab. 2): phenolic acids
(p-coumaric and ellagic acid); flavonols (quercetin, kaempferol);
ellagitannins and anthocyanins (pelargonidin and cyanidin deri-
vatives) (Fig. 1). The peaks were identified by comparing the UV-
visible spectra with those of the available standards. Further support
for this identification was obtained from their MS-MS analyses.
The lower peaks, without the typical spectral characteristic of the
standard, remained unidentified.
The phenolic contents were different for the five strawberry selec-
tions, with a mean of 63.46 mg/g fresh fruit. The concentration
ranged from 43.15 mg/100 g fresh fruit (163M88) to 75.53 mg/
100 g (160M77), showing statistically significant differences
(P<0.05) between the selections.

Ellagitannins
The ellagitannins only showed characteristic UV spectra for an
absorption maximum below 280 nm. Four peaks of ellagitannins
were found in all the strawberry extracts, except for the 148M6
selection which only had three peaks. Peak 2 had [M−H]− at m/z
935 and the main MS2 fragments at m/z 633 and m/z 301; it was
identified as galloyl-bis-HHDP-glucose. Peak 4 had [M−2H]2− at
m/z 935, corrsponding a mass of 1869. The MS/MS spectrum had an
M− at m/z 1869 which fragmented to produce m/z 1567 (M – 302,
a loss of a hexahydroxyphenoyl (HHDP) unit), 1265 (M – 302, a
further loss of HHDP), 1103 (M – 162, a loss of a glucosyl group),
933 (M – 170, a loss of a gallic acid) and 631 (M – 302, a loss of
HHDP). This peak was identified as sanguiin H-6 or agrimoniin,
which is a dimer of casuarictin/potentillin. Peak 5 had a λmax of
250 nm and, when subjected to acid hydrolysis, yielded ellagic
acid. The mass spectrum of this compound was complicated. It
showed a [M−2H]2- at m/z 1401. The main products were m/z 2019,
1869, 1567 (a loss of HHDP), 1402, 935, 897, 633 (a loss of tri-
HHDP-galloyl-glucose). This peak was identified as lambertianin
C, which is a trimer of casuarictin/potentillin. The late-eluting
ellagitannin compound (peak 9) remained unknown and requires
further identification.
The most abundant phenolic compounds found in strawberries
were ellagitannins, with an average of 30.77 mg/100 g, and they
showed statistically significant differences (P<0.05). The selections
containing the highest level of total ellagitanins were 29K55 and
160M77, with 37.94 and 34.94 mg/100 g, respectively.
The most important group within the ellagitanins was sanguiin-H6,
which on average reached 59 % of the total ellagitannins.

4 D. Donno, M. Cavanna, G.L. Beccaro, M.G. Mellano, D. Torello Marinoni, A.K. Cerutti, G. Bounous

Tab. 2: Phenolic compound contents of the strawberry selections. Results are expressed as mg per 100 gFW (mean ± SD, n=3). Values with different
letters showed statistically significant differences.

Compound strawberry selections
148M6 150M61 160M77 163M88 29K55

Anthocyanins
Cyanidin 3- glucoside 0.88± 0.08 1.47±0.09 1.21±0.14 0.65±0.04 1.39±0.04
Pelargonidin 3-glucoside 18.98±1.6 24.39±1.08 24.25±2.04 10.40±0.07 21.22±2.3
Pelargonidin 3-rutinoside 2.35±0.21 1.48±0.01 1.03±0.13 0.42±0.03 0.88±0.12
Pelargonidin 3- acetylglucoside nd 6.40±0.28 6.36±0.21 3.11±0.11 5.37±0.61
Total 22.21 b 34.28a 32.85a 14.59c 28.87a

Flavonols
Quercetin 3-glucoronide 1.03±0.02 1.18±0.06 0.56±0.02 0.83±0.01 1.71±0.11
Unknown 0.40±0.05 nd nd nd nd
Kaempferol 3-glucoside 0.07±0.01 0.18±0.01 0.10±0.01 nd 0.13±0.02
Total 1.50b 1.36b 0.66c 0.83c 1.84a

Ellagic acid
Ellagic rhamnoside 0.63±0.02 0.59±0.04 0.50±0.03 0.51±0.01 0.61±0.05
Ellagic rhamnoside 0.74±0.04 0.76±0.04 0.46±0.02 0.56±0.02 0.57±0.06
Total 1.37a 1.34a 0.95c 1.07bc 1.19ab

hydroxycinnamic acids
p-coumaric acid
4-glucoside 4.07±0.48a 4.49±0.32a 4.13±0.42a 0.33±0.04b 3.48±0.4a

Ellagitannins
Galloyl bis HHDP gluc. nd 4.18±0.94 4.28±0.18 3.29±0.29 5.11±0.73
Sanguiin -H6 16.34±0.34 15.28±1.89 21.06±0.84 17.79±0.51 20.27±1.2
Lambertianin C 5.59±0.04 5.57±1.07 5.44±0.55 1.64±0.06 7.84±1.13
Unknown 4.15±0.32 3.56±0.56 4.15±0.21 3.61±0.06 4.72±0.05
Total 26.08b 28.58b 34.94a 26.33b 37.94a

Total phenolic compounds 55.23b 70.07a 75.53a 43.15c 73.31a

Anthocyanins
The anthocyanins found in strawberries were glycosides of cyanidin
(λmax at 512 nm) and of pelargonidin (λmax at 495 nm). Peak 6 in
the DAD-chromatogram had an absorption maximum at 512 nm,
as well as molecular ions at m/z 447, with fragments at m/z 285 (a
loss of hexose) and was identified as cyanidin 3-glucoside. Three
peaks (7, 8 and 14) had absorption maxima at 495 nm as well as
MS fragmentation ions at m/z 269, and were identified as derivatives
of pelargonidin. Peak 7, with [M−H]− at m/z 431 and a subsequent
loss of 162 amu (hexose), was pelargonidin 3-glucoside. Peak 9,
with [M−H]− at m/z 577 and a loss of 308 amu (deoxyhexose-
hexose), was assigned as pelargonidin 3-rutinoside. One less polar
pelargonidin derivative, peak 14, had [M−H]− at m/z 473 as well as
a loss of 204, and was assigned as pelargonidin 3-acetylglucoside.
The total anthocyanins ranged from 14.59 mg/100 g (163M88) to
34.28 mg/100 g (150M61), with an average of 26.56, and showed
statistically significant differences (P<0.05). The 150M61, 160M77
and 29K55 selections showed the highest concentrations of all
studies. The lowest concentration was observed in 163M88.
Tab. 2 shows the single concentrations of the four major antho-
cyanins (i.e. Cy 3-gluc, Pg 3-gluc, Pg 3-rut and Pg 3-acetylgluc) in
the five strawberry selection extracts.
As far as the anthocyanins distribution is concerned, Pg 3-glucoside
was the predominant compound in the strawberries, representing
71 % of the total mean amount of anthocyanins, and this was

followed by Pg acetylglucoside, Pg 3-rutinoside and finally Cy 3-
glucoside.

Flavonols
The flavonols detected in the strawberries were derivatives of
quercetin and kaempferol. The flavonols were classified on the
basis of the shape of their UV-visible spectra, with an absorption
maximum at about 352 nm for quercetin glycosides and at about
344 nm for kaempferol glycosides. The shift in the UV maximum
from 352 to 344 nm is due to the lack of additional hydroxyl groups
attached to ring B in kaempferol, compared to quercetin. Three peaks
were detected in the UV-chromatogram, at tR 42, 48 and 50 min,
respectively. The peak 10 had a λmax of 365 nm. The mass spectrum
had an m/z 477 molecular ion that yielded an M-176 (cleavage of a
glucoronosyl unit) fragment ion at m/z 301, indicating the presence
of quercetin-3-glucuronide. Peaks 13 was identified as a kaempferol
derivative, due to its UV-spectrum and MS2 fragmentation ion at
m/z 285 in negative MS mode; this peak with [M−H]− at m/z 447
lost hexose (162 amu) during fragmentation, and was assigned as
kaempferol 3-glucoside. Peak 15 was identified as flavonol, due to
its UV-spectrum, but no further data could be obtained from LC-MS
analysis for its tentative identification.
The total flavonol contents ranged from 0.66 (160M77) to 1.84
(29K55) mg/100 g; the total levels were also statistically different

Nutraceutical profiles of currants and strawberries 5

Fig. 1: Chromatographic patterns of strawberry phenolic compounds obtained at 280, 320, 360 and 520 nm.
Peak assignment is provided on the right side.

(P<0.05). Quercetin 3-glucoronide was the most abundant flavonol
in these strawberry samples, with a concentration of 85.5 % of the
mean total flavonol content. Quercetin 3-glucoronide was the only

flavonol compound found in the 163M88 selection, while the 29K55
selection showed the highest values of this compound (1.71 mg/
100 g).

6 D. Donno, M. Cavanna, G.L. Beccaro, M.G. Mellano, D. Torello Marinoni, A.K. Cerutti, G. Bounous

Ellagic acid
Ellagic acid and its glycosides were distinguished by means of
their characteristic UV-visible spectra with absorption maxima at
254 and 360-368 nm, respectively. Two ellagic acids were detected
in the strawberry selections at 45 min and 45.4 min. Peaks 11 and
12 had [M−H]− at m/z 447. The MS2 products of the ions were at
m/z 301, with further fragmentation, being characteristic for ellagic
acid. These peaks were identified as ellagic acid rhamnoside. The
ellagic acid levels were between 0.95 (160M77) and 1.37 mg/100 g
(148M6), with a mean value of 1.19 mg/100 g, and showed
statistically significant differences (P<0.05).

hydroxycinnamic acids
The most important peak in the UV chromatogram obtained at
320 nm was for the hydroxycinnamic acids: peak 1 was identifed as
a p-coumaric ester (absorption maximum at 310 nm) (tR 17 min).

This peak had [M−H]− at m/z 487 with MS2 fragments at m/z 325
(loss of hexose). This compound was identified as a hexose ester (p-
coumaric acid 4-glucoside).
P-coumaric acid glucoside was the only hydroxycinnamic acid
found in the analyzed strawberry samples; its content varied from
0.33 mg/100 g (163M88) to 4.49 mg/100 g (150M61), and showed
statistical differences (p<0.05) with a mean of 3.30 mg/100 g.
Finally, the peaks indicated with number 3 were recognized as
generic procyanidins. The identification of this class of compounds
was based on the chromatographic behaviour, UV-vis spectra and a
comparison with literature. Quantification and identification of the
single peaks were not carried out.

Currants and goosberries
The protocol usually used for the identification of phenolics in
raspberries (Zafrilla et al., 2001) and in strawberries (allende

Fig. 3: HPLC separation of anthocyanins detected at 520 nm from red currant (cv Red poll).
Peak assignment is provided on the right side.

Fig. 2: HPLC separation of anthocyanins detected at 520 nm from black currant (cv Royal de Naples).
Peak assignment is provided on the right side.

Nutraceutical profiles of currants and strawberries 7

et al., 2007) was adapted for currants and gooseberries. Unfortunately,
it was not possible to provide the complete chromatographic pattern
of the phenolic compounds. In this study, only the anthocyanin
compound data were clear and have been reported.

Anthocyanins
The HPLC analyses of 29 different cultivars of Ribes spp. led to
the identification of 7 anthocyanins in Ribes nigrum L., 6 in Ribes
rubrum L., 3 in the hybrids and 2 in Ribes grossularia L.

Ribes nigrum l.
Peaks 1 and 2 were identified as two delphinidins (Fig. 2), the first
as delphinidin 3-glucoside, with [M−] at m/z 463 and a loss of 162
amu (hexose) and the second one as delphinidin 3-rutinoside with
[M−] at m/z 609 and a loss of 308 amu (deoxyhexose-hexose) upon
fragmentation.
Peak 3 was identified as cyanidin-3-rutinoside. The mass spectrum
of peak 4 revealed a small molecular ion at m/z 623 M− and a major
fragment ion at m/z 315; this corresponded to petunidin 3-rutino-
side (Mw 623), and the fragment ion [M – 308], which originated from
the loss of rutinoside moiety, resulted in petunidin (Mw 317). The
mass spectrum of peak 5 showed significant signals corresponding
to the peonidin 3-rutinoside molecular ion at m/z 607 M− and a major
fragment ion at m/z 299. Peak 6 revealed m/z 609 and m/z 301. These
masses corresponded to delphinidin 3-(6- coumaroyl)-glucoside and
its characteristic loss of m/z 308, the coumaroyl glucoside moiety,
which forms delphinidin. The last identified anthocyanin component
was cyanidin 3-(6-coumaroyl)-glucoside, which shows m/z 593 M−
and 285, corresponding to a loss of coumaroyl glucoside.
The anthocyanin content in black currant ranged from 47.03 (cv
Ben Sarek) to 661.81 mg/100 g (cv Invigo) with a mean value of
313.37 mg/100 g, and showed statistically significant differences
between groups (P<0.05). The most abundant anthocyanins found
in these cultivars of Ribes nigrum L. were delphinidin 3-rutinoside
and cyanidin 3-rutinoside with a mean value of 133.60 and
113.14 mg/100 g, respectively.

Ribes rubrum l., Ribes grossularia L. and hybrids
The first peak in the Ribes rubrum L. cultivars was identified as
anthocyanin, due to its UV-spectrum, but no further data were
obtained for its tentative identification from the LC-MS analysis
(Fig. 3). Peak 2 showed a shorter tR than those of the other peaks.
It had a delphinidin aglycon (fragment m/z 301 M−) and a molecular
weight of 595. The fragment loss was 294, which could be due to a
sambubiose residue. This anthocyanin was identified as delphinidin
3-sambubioside. The other four anthocyanins detected in the Ribes
rubrum L. cultivars were glycosides of cyanidin (λmax at 512 nm).
Peak 3 was identified as cyanidin 3- sophoroside. Peak 4 produced a
mass spectrum, with a M− at m/z 579, which yielded a fragment ion
at m/z 285 (M – 294) and was identified as cyanidin 3- sambubioside.
Peak 5 was recognized as cyanidin 3-xylosylrutinoside (Cy 3-
xylrut), presenting a molecular weight of 725 M− and a fragment
ion at m/z 285.
The last anthocyanin (peak 6) was identified as cyanidin 3-rutinoside.
Two anthocyanin compounds were detected in cv. Rokula, the only
Ribes grossularia L. cultivar: delphinidin 3-rutinoside and cyanidin
3-rutinoside.
Three anthocyanin compounds were detected in the two analyzed
hybrids: delphinidin 3-glucoside, delphinidin 3-rutinoside and
cyanidin 3-rutinoside. The anthocyanin content in the red currants,
gooseberries and hybrids ranged from 5.74 (gooseberry, cv Rokula)
to 85.74 mg/100 g (red currant, cv Jonker van Tets), with a mean

value of 33.83 mg/100 g, and showed statistically significant
differences (P<0.05). The anthocyanins in the Ribes rubrum L.
cultivars, ranged from 14.09 (cv Red win) to 85.74 mg/100 g (cv
Jonker van Tets), with a mean value of 38.29 mg/100 g.
The most abundant anthocyanin found in these cultivars of Ribes
rubrum L. was cyanidin 3-xylosylrutinoside, with an average
value of 21.80 mg/100 g. The Jogranda cultivar showed a higher
anthocyanin value (32.98 mg/100 g) among the hybrids.

Analysis of proanthocyanidins
The proanthocyanidins in the 10 analyzed cultivars of Ribes
spp. were procyanidins and prodelphinidin; (epi)catechin and
(epi)gallocatechin were present as subunits.

Analysis of vitamin C
strawberries
Statistically significant differences were found for the singular
AA and DHAA contents for the five analyzed strawberry se-
lections. The AA content ranged from 25.74 (150M61) to 30.36
(29K55) mg/100 g. the DHAA content varied from 3.03 (29K55)
to 7.46 (160M77) mg/100 g.
The total vitamin C content (AA+DHAA) varied from 31.74
(150M61) to 35.87 (160M77) mg/100 g, with a mean value of
33.32, but no statistically significant differences were observed
(Tab. 3).

Tab. 3: Ascorbic acid (AA) and dehydroascorbic acid (DHAA) contents.
Results are expressed as mg per 100 gFW (mean ± SD, n=3). Values
with different letters showed statistically significant differences.

Vitamin C

AA DHAA Total

Fragaria x ananassa
Duch.

163M88 26.72 ± 1.10 b 6.74 ± 1.11 a 33.46 ± 2.21 a
148M6 26.38 ± 0.55 b 5.78 ± 0.59 a 32.16 ± 1.14 a
150M61 25.74 ± 1.63 b 6.00 ± 0.64 a 31.74 ± 2.27 a
29K55 30.36 ± 0.91 a 3.03 ± 0.30 b 33.39 ± 1.21 a
160M77 28.41 ± 1.69 ab 7.46 ± 0.98 a 35.87 ± 2.67 a

Discussion
Phenolic compounds
strawberries
The phenolic compounds found in the five strawberry selections have
already been mentioned in literature, but different concentrations
have been found (aaBy et al., 2005). The selections that showed
the highest phenolic compounds were 160M77, 29K55 and 150M61.
The mean value of the phenolic compound concentration was
63.46 mg/100 g.
Ellagitannins were detected at 280 nm. The ellagitannins, together
with anthocyanins were the most abundant phenolic compounds
in the strawberries. In this study, ellagitannins were the main
phenolic class in the strawberries, representing 49 % of the analyzed
phenolic compounds; this result is in agreement with a previous
study performed by KähKönen et al., (2001). The mean content
of ellagitannins found in this research (30.77 mg/100 g) was within
the range found in literature (25-59 mg/100 g) (häKKinen and
törrönen, 2000; sKupien et al., 2004). Ellagitannins and ellagic
acid have been reported to show in vitro and in vivo antitumori-

8 D. Donno, M. Cavanna, G.L. Beccaro, M.G. Mellano, D. Torello Marinoni, A.K. Cerutti, G. Bounous

genic and antipromoting activities (larrosa et al., 2006); for this
reason, there is great interest in evaluating the concentrations of
ellagitannins and ellagic acid.
Ellagic acid is a dimeric derivative of gallic acid and is generally
recognized as a hydrolytic byproduct of the release of a hexa-
hydroxydiphenoyl (HHDP) ester group from ellagitannins, which
spontaneously converts to its characteristic bislactone structure.
Ellagic acid was mostly present as ellagitannins, and, in this
research, the relative amount of ellagic acid and its glycosides was
<2 % of the total phenolics. The mean content of ellagic acid found
in this study was 1.18 mg/100 g, a similar value to those previously
reported for strawberries by aaBy et al. (2005), but lower than the
values obtained by Koponen et al. (2007). This is feasible because
the present extraction used a medium containing acetone, as in aaBy
et al. (2005), whereas Koponen et al. (2007) applied acid hydrolysis,
which favours the release of ellagic acid from ellagitannins esterified
with glucose.
The second phenolic class in the strawberries was anthocyanins,
a result that is in agreement with the literature (KähKönen et al.,
2001). Anthocyanins are a group of flavonoids with exceptionally
good antioxidant properties, which have been attributed to the phe-
nolic hydroxyl groups attached to the ring structures (Wang et al.,
2002). The mean value of anthocyanins detected in this work was
26.56 mg/100 g; this value is similar, but slightly lower than that
found by määttä et al. (2004) (34.66 mg/100 g). Two anthocyanin
glycosides, pelargonidin 3-glucoside and cyanidin 3-glucoside, are
almost exclusively responsible for the red color of strawberries. In
this study, pelargonidin 3- glucoside was found to be the predominant
pigment of the strawberries, and on average represented 75 % of
the total anthocyanin content, in agreement with previous studies
(määttä et al., 2004). The fruit color is affected by many ecological
factors, such as light and temperature. For this reason, it is possible
to find differences in the anthocyanin concentration among studies
carried out under different climatic conditions.
The average flavonol content found in this study in the five strawberry
selections was 1.24 mg/100 g; a similar value of 2.03 mg/100 g was
found in the strawberries by määttä et al. (2004). It is important to
remember that the flavonoid content in strawberries (anthocyanins,
flavonols, catechins and flavanones), as in any other fruit, depends
on a series of factors, such as the stage of maturity, cultivar, storage
conditions and analytical methods, which can readily be inferred
from a comparison of different studies on this topic (miKKonen
et al., 2001).
Quercetin 3-glucuronide has been reported to be the main flavonol
in strawberry (aaBy et al., 2007), and, again in this work, it has
been the most abundant detected flavonol. Flavonols are usually
present in food as their glycosides, but are found in biological fluids
also as their glucuronidated derivatives (manach and donovan,
2004). P-coumaric acid 4-glucoside was the only hydroxycinnamic
acid detected in the analysed strawberry selections, with a mean
value of 3.30 mg/100 g, a comparable, but slightly higher value,
than formerly found by maatta et al. (2004) (2.57 mg/100 g) in
Fragaria x ananassa cultivars. The literature data confirm that p-
coumaric acid is the most abundant aglycon in strawberries. Soluble
hydroxycinnamic acids mainly occur as esters in berry fruit, except
in cloudberries (maatta et al., 2004); free hydroxycinnamic acids
have infrequently been reported in fruit, but it is possible that free
hydroxycinnamic acids are released at the late stages of ripening in
cloudberry, due to environmental stress factors, or that the unbound
acids are typical for these wild berries (Kumpulainen and salonen,
1996).

Currants and gooseberries
Anthocyanins are mportant polyphenolic components in Ribes spp.
(määttä et al., 2001). The mean content of anthocyanins found in

this work for the black currant cultivars was 313.37 mg/100 g; this
value was lower than the content of 476.17 mg/100 g found by Wu
et al. (2004). The most abundant anthocyanin found in these black
currant cultivars was delphinidin 3- glucoside, as demonstrated by
Wu et al. (2004).
The mean amount of anthocyanins detected in the red currant culti-
vars was 38.29 mg/100 g; this value was higher than that found by
Wu et al. (2004) (12.09 mg/100 g). The differences can be explained
by the fact that the average value in this work is a mean value
obtained from 13 different Ribes rubrum L. cultivars, while Wu
et al. (2004) analyzed just one cultivar. Cyanidin 3- xylosylrutinoside
was the most abundant anthocyanin detected in the analyzed red
currant cultivars, as already found by Wu et al. (2004).
Rokula, the only gooseberry cultivar considered in this research,
showed a mean anthocyanin value of 5.74 mg/100 g, a similar value
to that detected by Wu et al. (2004) (5.77 mg/100 g).
Finally, the two hybrids showed a mean anthocyanin value of
25.55 mg/100 g, a lower value than that found by Jordheim et al.
(2007). It is interesting to note that the individual anthocyanins,
identified in the two hybrids, reflected that these cultivars contained
more anthocyanins than both parents. This result confirms what has
already been observed by Jordheim et al. (2007).

Phloroglucinol: identification of proanthocyanidins
Proanthocyanidins are polymeric flavonoid compounds. In this study
it was possible to identify the different proanthocyanidins present
in 11 cultivars of Ribes spp. and the mDP (apparent mean degree
of polymerization) was also found. The mDP value was 19.60,
although the black currant cultivars showed a mDP of 22.42, a lower
value than that found by Wu et al. (2004) (47.90). This result can
be considered positive, because some studies have suggested that
low proanthocyanidin oligomers (DP<4) could be absorbed in the
gastrointestinal tract (santos-Buelga et al., 2000). Dimers have
been detected in human blood, after a proanthocyanidins-rich diet
has been consumed, while trimers have been shown to be absorbed
through the human intestinal cell line Caco-2 (depreZ et al., 2001).
For this reason, identification of heterogenous proanthocyanidins,
especially the low oligomers, are emphasized. (holt et al., 2002).

Analysis of vitamin C
The mean value of total vitamin C (ascorbic acid + dehydroascorbic
acid) contents in strawberry cultivars analyzed in this study was
33.32 mg/100 g; this value falls within the range of 23-47 mg/
100 g detected in strawberry genotypes by tulipani et al. (2008).
It has been demonstrated that strawberries are rich in vitamin C [a
handful of strawberries is sufficient to cover the recommended daily
allowance (RDA) of vitamin C] (tulipani et al., 2008).
In this study, the strawberries showed higher vitamin C values
compared to the other analyzed fruit, but lower than average values
of other fruit species, such as grapefruit (52 mg/100 g) or oranges
(46 mg/100 g), which are well known for their high vitamin C
content (proteggente et al., 2002).

Conclusions
The aim of this work was to contribute to the knowledge of the
nutraceutical features of some berry fruit species that so far have
been studied less than other berry species, such as blueberry and
raspberry.
As far as the Ribes spp. cultivars are concerned, the presence of
a high phenolic compound content, especially in Ribes nigrum
L., has been confirmed through qualitative analysis. Ribes spp.
cultivars can therefore be considered as an important source of

Nutraceutical profiles of currants and strawberries 9

antioxidant compounds. Moreover, the results have shown that
the tested strawberry cultivars and selections are good sources of
bioactive compounds, especially phenolics. In particular, selections
150M61, 160M77 and 29K55 have shown to possess the highest
values in polyphenol contents, among the analyzed strawberry fruit
selections.

Acknowledgements
Thanks are due to the Department of “Quality, safety and bioactivity
of plant foods, food science and technology” of “CEBAS” (Centro
de Edafologia y Biologia Aplicada del Segura), Murcia (Spain) for
their collaboration in this research.

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Address of the corresponding author:
E-mail: dario.donno@unito.it