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Ellagitannins from Strawberry with Different Degree of Polymerization Showed Different Metabolism Through Gastrointestinal Tract of Rats Joanna Milala, Monika Kosmala, El#bieta Karli#ska, Jerzy Juskiewicz, Zenon Zdunczyk, and Bartosz Fotschki J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.7b04120 • Publication Date (Web): 16 Nov 2017 Downloaded from http://pubs.acs.org on November 19, 2017
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Journal of Agricultural and Food Chemistry
Ellagitannins
from
Polymerization
Strawberry
Showed
with
Different
Different Metabolism
Degree
of
Through
Gastrointestinal Tract of Rats Joanna Milala,a* Monika Kosmala,a Elżbieta Karlińska,a , Jerzy Juśkiewicz,b Zenon Zduńczyk,b Bartosz Fotschkib a
Institute of Food Technology and Analysis, Lodz University of Technology, Stefanowskiego 4/10, 90-924 Lodz, Poland
b
Institute of Animal Reproduction and Food Research of the Polish Academy of Sciences, Division of Food Science, Tuwima 10, 10-748 Olsztyn, Poland
*
Corresponding
author,
(Tel:
+48
426312780;
Fax:
+48
426367488:
E-mail:
[email protected])
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Abstract
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The present paper describes a comparative study of the metabolism of 1) ellagic acid, 2)
3
monomeric ellagitannins – a mixture of α- and β-bis-hexahydroxydiphenoyl-D-glucose, and
4
3) dimeric ellagitannins – mainly agrimoniin with both glucose residues being esterified with
5
hexahydroxydiphenoyl (HHDP), in rats fed polyphenol-rich diets. Their metabolites were
6
identified and quantified in selected parts of the gastrointestinal tract i.e., the stomach, small
7
intestine, and cecum on the 2nd, 4th, and 7th day of the experiment, as well as in the feces,
8
blood serum, and urine of rats. Significant differences between the metabolites of strawberry
9
ellagitannins and ellagic acid were observed in all parts of the gastrointestinal tract. Urolithin
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A was the predominant polyphenolic metabolite of rats fed a diet supplemented with ellagic
11
acid. On the other hands, in rats fed low DP ellagitannins, the main metabolite was nasutin
12
followed by urolithin A, while ellagitannins with a higher DP led to nasutin only.
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KEYWORDS: ellagitannins, nasutin, urolithin, rat, agrimoniin, strawberry
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Introduction
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Epidemiological studies have shown that the consumption of fruits and vegetables reduces the
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risk of lifestyle diseases such as atherosclerosis, cancer, and neurodegenerative disorders. 1,2,3
18
1
19
cholesterol, low-density lipoprotein cholesterol, and triglyceride levels4, which is largely
20
attributable to the activity of polyphenols. Special attention has been attracted by ellagitannins
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(ETs), which are the most abundant strawberry polyphenols, along with anthocyanins and
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flavanols 5 In the study of Juśkiewicz et al .6 strawberry ET preparations were shown to lower
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lipemia and glycaemia.
Berry consumption beneficially modifies the lipid profile by significantly decreasing total
24
Ellagitannins can be defined as hexahydroxydifenoyl esters of carbohydrates of
25
cylitols as well as compounds derived from further oxidative transformations including
26
oligomerization processes.
27
differentiated in terms of the degree of polymerization (DP) and susceptibility to hydrolysis.
28
The elementary building blocks such as ellagic acid and HHDP may exist as free compounds
29
or may be generated as a result of hydrolysis of larger molecules. Ellagic acid is a product of
30
spontaneous lactonization within HHDP acid molecule.
9
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agrimoniin,
two
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hexahydroxydiphenoyl-D-glucose units linked by a C-O-C bond between two gallic acid
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residues.7,10 Raspberries and blackberries primarily contain sanguiin H-6 and lambertianin C,
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the monomeric units of which are linked with a sanguisorboyl group.7,11 These structural
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differences may affect the physiological activity of polyphenols from Rosaceae fruits. 12
a
7,8
GOG-type
ETs constitute a heterogeneous group of compounds
dimer
composed
of
The main strawberry ET is α-1-O-galloyl-2,3:4,6-bis-
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Polyphenols are known as antioxidants, but have a much wider spectrum of activity,
37
especially considering their low bioavailability as compared to endogenous antioxidants1 like
38
glutathione, alpha-lipoic acid, coenzyme Q, ferritin, uric acid, bilirubin. First of all, it must be
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remembered that large polyphenolic molecules cannot enter the bloodstream, in contrast to
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some simple polyphenols which are absorbed directly. The majority of ETs are hydrolyzed by
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colonic microorganisms, first into ellagic acid, and then into even smaller molecules, such as
42
urolithins. The pattern of urolithin formation seems to be as follows: after HHDP acid is
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released form ETs and converted into poly-hydroxylated dibenzopyranone, and then
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3,4,8,9,10-pentahydroxy-6H-dibenzo[b,d]pyran-6-one (Uro-M5). Subsequently, sequential
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dehydroxylation leads to tetrahydroxy- (Uro-M6 and Uro-D), trihydroxy- (Uro-M7 and Uro-
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C), dihydroxy- (Uro-A and IsoUro-A) and monohydroxy- (Uro-B) dibenzopyranones. These
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metabolites may be absorbed into the bloodstream and eventually accumulate in the urine in
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the form of glucuronides and sulfate conjugates; they can be also excreted in the
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feces.13,14,15,16,17,18 A fully validated methodology for urolithin determination in terms of
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linearity, sensitivity, precision, recovery, matrix effect, selectivity, stability in different
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biological samples and quantification was developed by García-Villalba et al.18, even though
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not all metabolites are commercially available.
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Depending on the host’s species and individual characteristics, the resulting
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metabolites may differ.19 20 The significance of polyphenolic metabolites, such as urolithins, is
55
not fully understood. It is known that they have antioxidant properties. Urolithins (especially
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A and C) were very active towards O2 •− direct scavenging, significantly inhibited neutrophil
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oxidative burst (stronger than ascorbic acid) 21.and/or activate phase II enzymes, which are
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involved in antioxidant functions or detoxification (thioredoxin reductase-1 or glutathione
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peroxidases)1, show anti-inflammatory activity, anti-estrogenic/estrogenic capacity due to
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structural analogy to estrogens, and anticancer effects.21,22,23,24 On the other hand, non-
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absorbable large compounds may influence the colonic microbiota with the result of
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stimulating the activity of some strains while inhibiting others.22 In our previous study, a
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strawberry polyphenolic extract improved the prebiotic effects of a fructooligosaccharide
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(FOS) diet, beneficially lowering cecal digesta pH and reducing putrefactive short-chain fatty
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acid production. On the other hand, the addition of dietary FOS enhanced the metabolism of
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the examined strawberry extracts in the cecum, thereby increasing the concentrations of
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polyphenolic metabolites in the cecal digesta and urine.25 Our subsequent study26 showed that
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the DP influenced the effectiveness of blood glucose reduction by polyphenolics, with
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monomers more readily mitigating sugar-induced postprandial glycemic loads. Furthermore,
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it was found that ETs contained in a monomeric ET-rich extract were more prone to intestinal
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breakdown in the cecum than those present in a dimeric ET-rich extract, and absorption of
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their metabolites could be increased by dietary FOS; together, they elicited strong
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antibacterial activity. 27 Interestingly, in previous investigations, nasutin was identified as one
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of ET metabolites in rats.12,27,28 This compound was previously found in the feces of some
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wild rodents, including beavers, and termites.13,19,29
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As molecular structure is important to the physiological function of ETs, the aim of
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this study was to identify and quantify the metabolites of ellagic acid and strawberry
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polyphenol preparations with monomeric (EM) and dimeric (ED) ellagitannins (Figure 1) in
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selected parts of the gastrointestinal tract of rats, i.e., the stomach, small intestine, and cecum,
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as well as in rat feces, blood serum, and urine.
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Methods
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Preparation of ET-rich strawberry extracts
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ET extracts were obtained from strawberry fruit pomace, a by-product in the manufacture of
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concentrated strawberry juice (ALPEX Co., Łęczeszyce, Poland), as described by Jurgoński
86
et al.27 In brief, fresh pomace was dried in an industrial vacuum dryer at 70±2°C and passed
87
through sieves. The seedless fraction was subjected to two-step extraction with 60% aqueous
88
solution of acetone. Next, after partial removal of the solvent via distillation, the resultant
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solutions were transferred onto a column packed with polymeric resin (Amberlite XAD 16,
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Sigma-Aldrich, Poznan, Poland). Sugars and other water-soluble compounds present in the
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solutions were eluted from the column with water. Then, fractions rich in monomeric and
92
dimeric ETs were desorbed with 10% and 40% aqueous solution of ethanol, respectively,
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concentrated to approx. 15% dry matter, and lyophilized (Table 1).
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Analytical methods
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Basic composition. AOAC methods 30 were used to determine dry matter and ash (940.26),
96
protein (920.152), crude fat (930.09), total dietary fiber (985.29), and insoluble dietary fiber
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(991.42).
98
Polyphenols: HPLC analysis. The concentration of ETs, ellagic acid, anthocyanins, and
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flavonols was determined in extracts diluted with methanol (1 mg/mL) using a Knauer
100
Smartline HPLC system with a photodiode array detector (Berlin, Germany) coupled with a
101
Gemini C18 column (110 Å, 250×4.60 mm; 5 µm, Phenomenex, Torrance, USA). The
102
detailed separation and detection conditions are described elsewhere Fotschki et al.
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following standards were used for the identification of polyphenols: ellagic acid, flavonols
104
(quercetin-3-O-glucoside, kaempferol-3-O-glucoside, quercetin, kaempferol, tiliroside),
105
pelargonidin-3-O-glucoside (all from Extrasynthese, Genay, France), p-coumaric acid
106
(Sigma-Aldrich), as well as ETs (bis-hexahydroxydiphenoyl-D-glucose and agrimoniin),
107
obtained by semi-preparative HPLC as described by Sójka et al. 10
25
. The
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The concentration of proanthocyanidins in the extracts was determined by HPLC
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following their breakdown in an acidic environment with excess phloroglucinol according to
110
Kennedy and Jones (2001). The obtained products were separated using a Knauer Smartline
111
chromatograph (Berlin, Germany) equipped with a UV–Vis detector (PDA 280, Knauer,
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Berlin Germany) and a fluorescence detector (Shimadzu RF-10Axl, Kyoto, Japan) coupled
113
with a Gemini C18 column (110 Å, 250×4.60 mm; 5 µm, Phenomenex, Torrance, USA). The
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separation conditions were as described by Kosmala et al.12 Identification was done at 280 nm
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using a UV–Vis detector and the following standards: (–)-epicatechin, (+)-catechin, and (–)-
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epigallocatechin, and their respective phloroglucinol adducts. Phloroglucinol adducts were
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previously synthetized and isolated from corresponding standard. Quantification was carried
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out by measuring peak areas recorded by the fluorescence detector (excitation wavelength:
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278 nm; emission wavelength: 360 nm). The breakdown products were quantified using
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standard
121
(–)-epicatechin-phloroglucinol adduct for extender units.
curves
of
(–)-epicatechin
and
(+)-catechin
for
terminal
units
and
122 123
High Performance Liquid Chromatography – Electrospray Ionization – Mass Spectrometry
124
(HPLC-ESI-MS).
125
Ellagitannins were confirmed by HPLC-ESI-MS using a Dionex UltiMate 3000 UHPLC and
126
a Thermo Scientific Q Exactive series quadrupole ion trap mass spectrometer (Jurgoński et
127
al., 2015). A Phenomenex Luna 5 µm C18 (250 × 4.6 mm) column was used with a binary
128
gradient of 1% formic acid as mobile phase A and water/acetonitrile (1:4 v/v) as mobile phase
129
B at a flow rate of 1.0 mL/min. The gradient program was 5% of mobile phase B for the first
130
6.5 min, 5–15% B from 6.5 to 12.5 min, 15–45% B from 12.5 to 44 min, 45–75% B from 44
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to 45 min, isocratic conditions at 75% B from 45 to 50 min, 75–5% B from 50 to 52 min, and
132
column equilibration at 5% B from 52 to 65 min. Mass spectrometry analysis was performed
133
in negative ion mode under the following conditions: capillary voltage +4 kV, sheath gas
134
pressure 75 au (arbitrary units), auxiliary gas at 17 au, and scan range from 200 to 2000 m/z.
135 136
In vivo experiments
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Animals and diets. Experiments were conducted on 30 male Wistar rats aged approx. 4 weeks,
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randomly assigned to one of three groups of ten rats each. The animals were maintained
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individually in metabolic cages at a stable temperature (21–22°C), a 12 h light:12 h dark
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cycle, and a ventilation rate of 20 air changes per hour. The rats were used in compliance with
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the European guidelines for the care and use of laboratory animals (EU Directive
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2010/63/EU), and the animal protocol was approved by the Local Institutional Animal Care
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and Use Committee (permission number 32/2012). Individual body weight and food intake
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data were recorded. Samples of intestinal digesta, feces, urine, and blood were collected after
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2, 4 and 7 days of experimental feeding, from 3 rats each time. All urine and feces for 24 h
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were collected to measure how much of ET and ellagic acid metabolites was produced during
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1 day. The rats had free access to tap water and semipurified diets, which were prepared and
148
then stored at 4°C in sealed containers until the end of the experiment. The diets were
149
modifications of a casein diet for laboratory rodents recommended by the American Institute
150
of Nutrition
151
achieve a final concentration 0.1% of ellagitannins or ellagic acid. The composition of
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experimental diets is summarized in Table 3. All diets contained 3% FOS to mitigate any
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potential negative effect of polyphenols on the fermentative function of the large gut
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microbiota 32. Three individuals from each experimental group fed polyphenol-rich diets were
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anesthetized after 2 days, another 3 after 4 days, and the rest after 7 days in order to collect
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intestinal digesta and blood samples. Three rats fed a control diet without polyphenols were
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sacrificed after 7 days of the experiment. Urine was collected after 1, 2, 4, and 7 days, and
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feces were collected after 1, 4, and 7 days. Upon the termination of the experiment, the rats
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were weighed and anesthetized with 50 mg sodium pentobarbital/kg body weight (they were
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not deprived of feed prior to anesthesia). Following laparotomy, blood samples were collected
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from the caudal vein and serum was prepared by solidification and low-speed centrifugation
162
(350×g, 10 min, 4°C). Serum samples were kept frozen at -70°C until assayed. Selected
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intestinal segments (stomach, small intestine, cecum) were removed, and samples of digesta
164
were collected.
31
.Polyphenolic preparations were added to the diets in such proportions as to
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Free ellagic acid and ET metabolites in stomach, small intestinal, and cecal digesta and
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feces. Extraction of free ellagic acid and ET metabolites was carried out using 100% and 70%
167
acetone. To 500 mg of digesta or feces 2 mL of 100% acetone was added, mixed, sonicated
168
for 10 min, and centrifuged (800 rad/s). The procedure was repeated twice with 1.5 mL of
169
70% acetone and the extracts were combined, evaporated to dryness under vacuum, dissolved
170
in 1 mL of 100% methanol and analyzed with HPLC. For HPLC parameters see Polyphenols:
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HPLC analysis. Detection was performed at 360 nm. Standards used were: Ellagic acid,
172
Urolithin A, Urolithin B (Sigma Aldrich, Steinheim, Germany). Urolithin A glucuronide was
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prepared as described by Cerdá et al. (2004).18 The raw material for the isolation of urolithin
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A glucuronide was two liters of urine from three healthy volunteers (25−45 years old) who
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consumed 400 g of strawberry per day, as described in Fotschki et al. (2014).Nasutin was
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isolated from rats fed ellagitannin preparation faeces in the same manner. Identification of
177
metabolites was confirmed by HPLC-MS and compared with literature.
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the ellagitannin metabolites was presented in Table 2.
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Urine samples. Urine (2–4 mL) was acidified with 0.25 mL of 1 mol/L H3PO4 and was
180
applied to a 60 mg SPE Strata X-33 column conditioned according to the manufacturer’s
181
instructions (Phenomenex, Torrance, USA). The column was washed with 3 mL of water, 3
182
mL of 0.1 mol/L acetate buffer, and 6 mL of water, and dried. The analyte was eluted with
183
100% methanol (2 × 0.5 mL) and analyzed by UHPLC-MS.
184
The metabolites were determined by HPLC-ESI-MS using a Dionex UltiMate 3000 UHPLC
185
and a Thermo Scientific Q Exactive series quadrupole ion trap mass spectrometer. The
186
column was a Kinetex 2.6 µ C 18 100 Å; 150×2.1 mm (Phenomenex, Torrance, CA, USA)
187
kept at 35°C. A binary gradient of 0.1% formic acid as mobile phase A and 0.1% formic acid
188
in acetonitrile as mobile phase B was used at a flow rate of 0.5 mL/min. The gradient program
189
was 5% of mobile phase B for the first 1.44 min, 5–15% B from 1.44 to 2.98 min, 15–40% B
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Recovery of
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from 2.98 to 10.1 min, 40–73% B from 10.1 to 11.5 min, isocratic conditions at 73% B from
191
11.55 to 12.7 min, 73–5% B from 12.7 to 13.28 min, and column equilibration at 5% B from
192
13.28 to 18 min. Mass spectrometry analysis was performed in negative ion mode under the
193
following conditions: capillary voltage +4 kV, sheath gas pressure 60 au (arbitrary units),
194
auxiliary gas 10 au, and scan range from 120 to 1200 m/z.
195
Blood serum samples. To 0.5 mL serum 1 mL 100% acetone was added, mixed, sonicated for
196
10 min, and centrifuged (900 rad/s). The procedure was repeated with 1.0 mL of 100%
197
acetone and the extracts were combined and evaporated to dryness under vacuum in a
198
ScanSpeed 40 low speed centifuge (Labogene, Denmark), lyophilized in an Alpha 1-2 LD
199
plus freeze dryer (Germany), solubilized in 0.2 mL of 100% methanol, and then analyzed by
200
UHPLC-MS (parameters as for urine).
201
Statistical analysis. The results are expressed as means and pooled SEM. Two-way analysis
202
of variance (ANOVA) was used to evaluate the effects of polyphenolic supplementation (S;
203
extracts rich in monomeric or dimeric ETs, and ellagic acid), feeding duration (D; 2, 4, 7 days
204
for gastrointestinal digesta and feces and blood samples and 1, 2, 4, 7 days for urine samples),
205
and interactions between these two factors (S × D). If analysis revealed a significant
206
interaction (P≤0.05), differences between the respective study groups were determined with
207
Duncan’s post hoc test at P≤0.05. Statistical analysis was performed using STATISTICA
208
software, version 10.0 (StatSoft Corp., Cracow, Poland).
209 210
Results
211 212
The preparations used in the experiment were characterized by a high content of polyphenols,
213
more than 95%, mostly ellagitannins. Both preparations, EM and ED, contained ellagitannins
214
typical for strawberry fruits.5,6,7,10,12 EM was characterized by a high quantity of monomeric
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ellagitannins, 67%, while ED was characterized by a high quantity of dimeric ellagitannins,
216
mostly agriimonin. Structures are presented in Figure 1. The remaining polyphenols were
217
proanthocyanidins, 27 and 11% respectively, which are difficult to separate. Both
218
preparations were deprived of other groups of polyphenols like anthocyanins or flavonols
219
(Table 1).
220
The highest concentration of ellagic acid in stomach digesta was found in rats fed a diet
221
supplemented with ellagic acid (EA treatment) with the difference being statistically
222
significant (P
