In the last two decades, an increasing interest has been observed in the health-promoting properties of particular food constituents, including dietary fibre–polyphenolic complexes. Chicory belongs to plants of the Compositae family, accumulating energy in the form of the fructan inulin, the physiological (i.e. prebiotic) properties of which have been described in numerous studies. The available literature lacks comprehensive reports on the contents of individual active substances in the leaves and roots of chicory, particularly polyphenolic compounds. In the case of artichoke (Cynara scolymus L.), the leaves of which contain a similar array of biologically active substances as in chicory, the data are more compendious and more easily available(Reference Fratianni, Tucci and De Palma1). The main components of chicory roots and leaves belonging to a group of phenolic compounds include monocaffeoylquinic acids (MCQA, e.g. chlorogenic acid being an ester of quinic and caffeic acids), dicaffeoylquinic acids (DCQA, e.g. cynarine, i.e. 1,5-DCQA) and chicoric acid. It has been reported that a high percentage of dietary chlorogenic and caffeic acids is not absorbed from the gastrointestinal tract of humans and may exhibit a variety of intestinal effects(Reference Olthof, Hollman and Katan2). In vitro investigations have demonstrated that chlorogenic acid inhibits the process of DNA damage and the synthesis of mutagenic and carcinogenic N-nitroso compounds(Reference Kono, Shibata and Kodama3). In turn, caffeic acid and its derivatives have been shown to display antiproliferative activity in vitro against neoplastic cells(Reference Balasundram, Sundram and Samman4). Both dietary chlorogenic and caffeic acids may mitigate the risk of CVD through diminished oxidation of both the LDL-cholesterol fraction and total cholesterol(Reference Nardini, D'Aquino and Tomassi5). Also, in other studies, chlorogenic acid was found to decrease the levels of total cholesterol and TAG in the blood serum of obese, hyperlipidaemic and insulin-resistant rats, as well as to increase glucose tolerance, to decrease the pool of serum and liver lipids and to improve distribution of minerals, thus increasing insulin sensitivity(Reference Rodriguez and Hadley6).
Sparse studies on DCQA, particularly on their 1,5-(cynarine), 3,4-, 3,5- and 4,5-isomers, point to their antimutagenic, anti-inflammatory, hypocholesterolaemic and hepatoprotective activity(Reference Yashimoto, Yahara and Okuno7). Some studies also indicate their antiviral activity, with the highest one ascribed to 1,3-DCQA(Reference Slanina, Taborska and Slaninova8).
The present study was aimed at identifying the physiological effects of the coupled action of metabolites of endogenous digestion of a dietary fibre fraction and polyphenols from chicory. The following hypothesis was advanced: the dietary concomitant occurrence of prebiotic fructans and different phenolic compounds originating from chicory roots, seeds and leaves may further influence caecal physiology, antioxidant status and lipoprotein profile in rats.
Materials and methods
Chicory preparations
Raw chicory (Cichorium intybus L.) was provided by Cykoria Company (Wierzchosławice, Poland), a company specialised in its processing. Preparation was carried out as previously reported(Reference Milala, Grzelak and Król9). Briefly, after drying at < 70°C, the root cubes (2 kg), peel (2·5 kg), leaves (1·3 kg) and seeds (1 kg) were extracted with 75 % ethanol. Dried roots and peel were extracted once for 3 h in a continuous manner, while leaves and seeds were extracted consecutively (four times), with a sample-to-solvent ratio of 1:3. The total volume of ethanol used for obtaining the root and peel extracts was 18 and 20 litres, respectively. The extraction procedure was performed in hermetic containers and without light access from outside. The ethanol was removed by vacuum distillation and the extracts were further freeze-dried for 24 h beginning at − 30°C, followed by an additional drying at 40°C for 2 h. The final extraction yields (defined as the mass of extract per unit mass of sample) were 33·0 % from roots, 17·6 % from peel, 10·0 % from leaves and 3·5 % from seeds. The composition of the extracts is given in Table 1.
DP, degree of polymerisation; CQA, caffeoylquinic acids.
Chemical analyses of the plant material
DM, ash, protein and fat contents in the chicory extracts were determined according to the official method of Association of Official Analytic Chemists nos 934.01, 940.26, 920.152 and 930.09, respectively(10).
Carbohydrate determinations were performed using HPLC (Knauer Smartline with an RI K-2301 Knauer detector (Berlin, Germany), an Animex HPX 87C (300 × 7·8 mm) column and water as a mobile phase (flow rate, 0·5 ml/min; temperature, 85°C)). A sample of the tested preparation (0·5–1 g) was dissolved in water (10 ml) and passed through a column filled with a mixture of cation and anion exchangers (a 1:2 ratio). The first 5 ml of the filtrate were rejected and the next 4 ml were collected. Of these, 2 ml were used directly for the analysis of monosaccharides and disaccharides. The remaining 2 ml were diluted twice and used for the determination of fructo-oligosaccharides, after previous desalting and mixing with acetonitrile (a 1:1 ratio) according to the procedure of Król & Grzelak(Reference Król and Grzelak11).
Phenolic determinations were performed, according to the procedure of Milala et al. (Reference Milala, Grzelak and Król9), using HPLC (a Dionex system with a diode array detector (Germering, Germany), coupled with a 4 μm Fusion-RP 80A column (150 × 2·0 mm; Phenomenex Synergi, Torrance, CA, USA)). The elution solvents were A (0·05 % phosphoric acid in water) and B (0·05 % phosphoric acid in acetonitrile). A flow rate of 0·25 ml/min and a temperature of 25°C were set as the operating conditions. For the linear gradient method, the program started with 4–50 % B from 0 to 33 min, 50 % B from 33 to 34 min, 4 % B from 34 to 35 min and a post-run with 4 % B for 10 min to equilibrate the column for the next injection. The absorbance was measured at 325 and 360 nm. Hyperoside, quercetin glucoside, apigenin and luteolin were purchased from Extrasynthese (ZI Lyon Nord, Genay, France). Chicoric acid (dicaffeoyltartaric acid) was isolated from the leaves as described elsewhere(Reference Scarpati and Oriente12), and its purity was confirmed by UV spectroscopy, optical rotation and HPLC. DCQA was a pure substance isolated by semi-preparative HPLC (column, 250 × 10 mm (Phenomenex); volume of injection, 200 μl; flow rate, 5 ml/min; eluent as above) from the root extracts and was confirmed by the MS spectrum (fast atom bombardment-MS [M − H]− , 515·3; MAT95 mass spectrometer, Finnigan MAT GmbH, Bremen, Germany). Quercetin glucuronide was isolated from the leaf extract by semi-preparative HPLC and was confirmed by UV and MS spectra (column, 250 × 10 mm (Phenomenex); injection volume, 200 μl; flow rate, 5 ml/min; eluent as above). All aforementioned substances were used as identification standards by comparison of retention times and UV spectra, and additionally by comparision with the data obtained previously(Reference Chkhikvishvili and Kharebova13, Reference Mulinacci, Innocenti and Gallori14). All hydroxycinnamic acids were calculated as chlorogenic acid (3-caffeoylquinic acid (CQA)) and all polyphenolic glycosides as quercetin glucuronide (Sigma, St Louis, MO, USA).
Animal study
The animal protocol used in the present study was approved by the Local Institutional Animal Care and Use Committee. The assessment was conducted on forty male Wistar rats aged 35 d and weighing 103·1 (sd 4·25) g, and are divided into five groups of eight animals each. All animals were housed individually over 4 weeks in metabolism cages with free access to water and semi-purified casein diets (Table 2). The selection of the rats and their maintenance over the 28 d experiment followed the common regulations. The environment was controlled with a 12 h light–12 h dark cycle, a temperature of 21 ± 1°C, a relative humidity of 50 (sd 5) % and twenty air changes/h. All experimental diets were similar in terms of dietary ingredients except for the phenolic fraction, and especially the CQA thereof. The diets were adjusted to the level of carbohydrates and the degree of polymerisation of fructans with the calculated amounts of phenolics. The adjustment of fructans was performed using commercial preparations: Frutafit® TEX! with degree of polymerisation >10 (Sensus, Roosendaal, The Netherlands) and Raftilose® P95 with degree of polymerisation 3–7 (Orafti, Oreye, Belgium). The control diet contained no phenolics. A diet supplemented with 10 % of the root extract (the PL diet) contained 0·05 % of CQA (MCQA:DCQA, 60:40), a diet supplemented with 6·5 % of the peel extract (the PM diet) contained 0·107 % of CQA (MCQA:DCQA, 54:46), a diet supplemented with 8 % of the peel extract and 0·8 % of the seed extract (the PH diet) contained 0·208 % of CQA (MCQA:DCQA, 45:55) and a diet supplemented with 2·5 % of the leaf extract (the PMc diet) with 0·106 % of the total phenolics. The percentage composition of the phenolic fraction in the PMc diet was as follows: MCQA:DCQA:chicoric acid:quercetin glucuronide, 30:2:50:18. In all experimental diets, the extracts were added at the expense of sucrose, fructans and maize starch.
C, control; PL, diet supplemented with 10 % of root extract; PM, diet supplemented with 6·5 % of peel extract; PH, diet supplemented with 8 % of peel extract and 0·8 % of seed extract; PMc, diet supplemented with 2·5 % of leaf extract with 0·106 % of total phenolics; DP, degree of polymerisation; FOS, fructo-oligosaccharides; MCQA, monocaffeoylquinic acid; DCQA, dicaffeoylquinic acid.
* Casein preparation containing 89·7 % protein, 0·3 % fat, 2·0 % ash and 8·0 % water (Lacpol Company, Murowana Goslina, Poland).
† Kruszwica SA Company, Kruszwica, Poland.
‡ Sigma, Poznan, Poland.
§ AIN-93G-MX (per kg mix): 357 g calcium carbonate anhydrous (40·04 % Ca), 196 g potassium phosphate monobasic (22·76 % P and 28·73 % K), 70·78 g potassium citrate, tripotassium monohydrate (36·16 % K), 74 g NaCl (39·34 % Na and 60·66 % Cl), 46·6 g potassium sulphate (44·87 % K and 18·39 % S), 24 g magnesium oxide (60·32 % Mg), 6·06 g ferric citrate (16·5 % Fe), 1·65 g zinc carbonate (52·14 % Zn), 1·45 g sodium meta-silicate.9H2O (9·88 % Si), 0·63 g manganous carbonate (47·79 % Mn), 0·3 g cupric carbonate (57·47 % Cu), 0·275 g chromium potassium sulphate.12H2O (10·42 % Cr), 81·5 mg boric acid (17·5 % B), 63·5 mg sodium fluoride (45·24 % F), 31·8 mg nickel carbonate (45 % Ni), 17·4 mg lithium chloride (16·38 % Li), 10·25 mg sodium selenate anhydrous (41·79 % Se), 10 mg potassium iodate (59·3 % I), 7·95 mg ammonium paramolybdate. 4H2O (54·34 % Mo), 6·6 mg ammonium vanadate (43·55 % V) and 221·026 g powdered sucrose.
∥ AIN-93G-VM (g/kg mix): 3·0 nicotinic acid, 1·6 calcium pantothenate, 0·7 pyridoxine–HCl, 0·6 thiamin-HCl, 0·6 riboflavin, 0·2 folic acid, 0·02 biotin, 2·5 vitamin B12 (cyanocobalamin, 0·1 % in mannitol), 15·0 vitamin E (all-rac-α-tocopheryl acetate, 500 mg/g), 0·8 vitamin A (all-trans-retinyl palmitate, 275 mg/g), 0·25 vitamin D3 (cholecalciferol, 10 mg/g), 0·075 vitamin K1 (phylloquinone), 974 655 powdered sucrose.
¶ AVEBE, Veendam, Holland.
During the study, the rats were subjected to N balance that was preceded by a 10 d preliminary period. In the 5 d period of the proper experiment, faeces and urine were thoroughly collected from all the rats that were kept in balance cages (Tecniplast Spa, Buguggiate, Italy). The content of total N in the diets, faeces and urine collected in the balance period was assayed using the Kjeldahl method.
The experimental groups were additionally monitored for body-weight gains and diet intake, which enabled the calculation of the feed conversion ratio. Faecal pH was measured using a microelectrode and a pH/ion meter (model 301; Hanna Instruments, Vila do Conde, Portugal) after the first, second, third and fourth week of experimental feeding. At the termination of the experiment, the rats were anaesthetised with sodium pentobarbital according to the recommendations for euthanasia of experimental animals. After laparotomy, blood samples were taken from the caudal vena cava, and then small intestine, caecum, colon, liver, heart, kidneys and lungs were removed and weighed. The small intestine was divided into four equal parts, and the second part (jejunum) from the stomach side was rinsed with ice-cold physiological saline and cut open. The mucosal samples were collected by scraping with glass slides on an iced glass plate, weighed and subsequently stored at − 40°C. Disaccharidase (sucrase, maltase and lactase) activity was assayed using the method of Messer & Dahlqvist(Reference Messer and Dahlqvist15) with modifications. The amount of liberated glucose was measured spectrophotometrically and the enzyme activity was expressed as μmol disaccharide hydrolysed/min per g of protein. Samples of caecal contents were used for immediate analysis (NH3, DM and SCFA), while the rest of the caecal digesta was transferred to tubes and stored at − 70°C. From the fresh caecal digesta, NH3 was extracted, trapped in a solution of boric acid in Conway's dishes and determined by direct titration with H2SO4. The DM of the digesta was determined at 105°C.
Caecal digesta samples were subjected to SCFA analysis, using GC (Shimadzu GC-2010, Kyoto, Japan). The samples (0·2 g) were mixed with 0·2 ml formic acid, diluted with deionised water and centrifuged at 7211 g for 10 min. The supernatant was loaded onto a capillary column (SGE BP21, 30 m × 0·53 mm) using an on-column injector. The initial oven temperature was 85°C and was raised to 180°C by 8°C/min and held there for 3 min. The temperatures of the flame ionisation detector and the injection port were 180 and 85°C, respectively. The sample volume for GC analysis was 1 μl. The caecal SCFA pool size was calculated as the sum of the SCFA concentration in the digesta and caecal digesta mass.
The activity of bacterial enzymes (β-glucosidase and β-glucuronidase) released into the environment was measured by the rate of p- or o-nitrophenol release from their nitrophenylglucosides, according to the method described elsewhere(Reference Juśkiewicz, Wróblewska and Jarosławska16), in fresh faeces, which were taken after each week of the experiment, and in the caecal digesta on termination of the experiment (α- and β-glucosidase, α- and β-galactosidase and β-glucuronidase). The following substrates were used: p-nitrophenyl-α-d-glucopyranoside (for α-glucosidase); p-nitrophenyl-β-d-glucopyranoside (for β-glucosidase); p-nitrophenyl-α-d-galactopyranoside (α-galactosidase); o-nitrophenyl-β-d-galactopyranoside (β-galactosidase); p-nitrophenyl-β-d-glucuronide (for β-glucuronidase). The reaction mixture contained 0·3 ml of a substrate solution (5 mm) and 0·2 ml of a 1:10 (v/v) dilution of the caecal/faecal sample in 100 mm phosphate buffer (pH 7·0) after centrifugation at 7211 g for 15 min. Incubation was carried out at 37°C and p-nitrophenol was quantified at 400 and 420 nm (o-nitrophenol concentration) after the addition of 2·5 ml of 0·25 m-cold sodium carbonate. The enzymatic activity (α- and β-glucosidase, α- and β-galactosidase and β-glucuronidase) was expressed as μmol product formed/h per g of digesta.
The extent of lipid peroxidation in selected tissues (kidneys, lungs, liver and heart) and in the serum was measured by quantifying malondialdehyde formed in terms of thiobarbituric acid-reactive substances (TBARS)(Reference Uchiyama and Mihara17). Serum concentrations of TAG, total cholesterol and its HDL fraction were estimated with reagents from Alpha Diagnostics Limited (Warsaw, Poland). The activity of glutathione peroxidase in the heparinised blood and superoxide dismutase in the erythrocyte lysate were determined using reagents from Randox Laboratories Limited (Crumlin, Antrim, UK). The serum antioxidant capacity of water-soluble (ACW) and the antioxidant capacity of lipid-soluble (ACL) substances (kit; Analytik Jena AG, Jena, Germany) were determined by a photochemiluminescence detection method, using a Photochem (Analytik Jena AG). In the photochemiluminescence assay, the generation of free radicals was partially eliminated by the reaction with antioxidants present in the serum samples, and the remaining radicals were quantified by luminescence generation. Ascorbate and Trolox calibration curves were used in order to evaluate ACW and ACL, respectively, and the results were expressed as μmol ascorbate or Trolox equivalents/ml serum.
Statistical analyses
Results were analysed statistically using one-way ANOVA, and the significance of differences between groups was determined using Duncan's multiple-range test at a significance level of P ≤ 0·05. Data are expressed as means and standard deviations. Calculations were made with STATISTICA 8.0 (StatSoft Corporation, Kraków, Poland).
Results
The presence of the polyphenolic fraction in the experimental diets had no effect on the faecal pH value measured after the first and second week of the experiment (Table 3). The faecal pH value of rats measured on days 21 and 28 of the experiment was significantly higher in the PMc group than in the control (C), PL and PM groups. The activity of faecal β-glucosidase released into the environment on day 21 of the experiment turned out to be significantly lower in the PM and PMc groups compared with the C group. After 4 weeks of feeding with the experimental diets, faecal β-glucosidase activity in the C and PL groups was significantly higher than in the other groups. Diet supplementation with the preparations examined did not result in any significant differences in faecal β-glucuronidase activity on day 7 of experimental feeding, while on day 14, its activity in the PMc group was significantly higher than in the faeces of rats fed the PM and PH diets. No significant differences were observed between the C group and the experimental groups in the second week of the experiment. In turn, after 3 and 4 weeks of the study, faecal β-glucuronidase activity was highest in the C group and differed significantly from the value determined in the PM and PH groups.
C, control; PL, diet supplemented with 10 % of root extract; PM, diet supplemented with 6·5 % of peel extract; PH, diet supplemented with 8 % of peel extract and 0·8 % of seed extract; PMc, diet supplemented with 2·5 % of leaf extract with 0·106 % of total phenolics.
a,b Mean values within a row with unlike superscript letters were significantly different (P ≤ 0·05).
* Experimental factor in particular groups: PL, contained 10 % of chicory root extract; PM, contained 6·5 % of a chicory peel extract; PH, contained 8 % of a chicory root peel extract and 0·8 % of a chicory seed extract; PMc, contained 2·5 % of a chicory leaf extract. The content of dietary polyphenols in the experimental groups was as follows: C, 0 %; PL, 0·050 %; PM, 0·107 %; PH, 0·208 %; PMc, 0·106 %.
The chicory preparations applied in the study had no significant effect on the body-weight gains of rats, diet intake and feed conversion ratio (Table 4). The rats fed the diet with the highest content of polyphenols (the PH group) excreted the highest quantity of faecal N within 5 d of the balance study, with the quantity being significantly higher than that recorded in the C group. When losses of N with faeces were expressed in percentage of ingested N, no differences were observed between the C group and the experimental groups, while the value of that parameter was significantly higher in the PMc group compared with the PM group. For this reason, the value of N apparent digestibility index differed significantly only between the PM and PMc groups (PM>PMc; P ≤ 0·05). The quantity of N excreted with urine was significantly lower in the C and PMc groups than in the other groups. The N retention index, considering losses of N both with faeces and urine, did not differ statistically between the groups. The 4-week administration of the PMc diet to rats evoked a significant increase in the pH of the small-intestine digesta and in the mucosal sucrase activity compared with the C diet. The highest level of diet supplementation with the polyphenolic compounds of chicory (the PH diet) significantly increased the mass of both the caecal wall and digesta (P ≤ 0·05 v. C group). The caecal digesta of the PH group was also characterised by the lowest DM concentration (P ≤ 0·05 v. PMc).
C, control; PL, diet supplemented with 10 % of root extract; PM, diet supplemented with 6·5 % of peel extract; PH, diet supplemented with 8 % of peel extract and 0·8 % of seed extract; PMc, diet supplemented with 2·5 % of leaf extract with 0·106 % of total phenolics; BW, body weight; FCR, feed conversion ratio.
a,b Mean values within a row with unlike superscript letters were significantly different (P ≤ 0·05).
* μmol/min per g of protein.
The experimental diets applied in the discussed experiment did not have any significant effect on the activities of the examined intestinal microbiota enzymes released into the caecal environment, except for the activity of β-glucuronidase (Table 5). Its activity diminished significantly in the PH group (P ≤ 0·05 v. C group). In the PH and PMc groups, a tendency for an increasing activity of bacterial α-galactosidase was observed, with respect to the C group (P = 0·062 and 0·059, respectively). The experimental treatments did not affect the concentration of the total SCFA in the caecal digesta. The concentrations of individual fatty acids were the same in all groups, yet the highest level of polyphenols in the PH diet caused a significant decrease in the concentration of propionic acid in the PH group compared with the C group (P ≤ 0·05). When comparing the C group with particular experimental groups, no significant differences were determined in the size of the total SCFA pool nor in the pools of individual acids. Only the pools of the total SCFA and acetic acid in the PH group turned out to be significantly higher in comparison with rats fed the PL diet.
C, control; PL, diet supplemented with 10 % of root extract; PM, diet supplemented with 6·5 % of peel extract; PH, diet supplemented with 8 % of peel extract and 0·8 % of seed extract; PMc, diet supplemented with 2·5 % of leaf extract with 0·106 % of total phenolics; BW, body weight.
a,b Mean values within a row with unlike superscript letters were significantly different (P ≤ 0·05).
Out of all groups assayed, the PM group was characterised by the highest serum ACW and, simultaneously, by the lowest serum ACL values (Table 6). These differences were statistically significant compared with the C group and in the case of ACL – also compared with the PL group. In the lung tissue of rats administered the PH and PMc diets, the concentration of TBARS was significantly lower than that determined in the C group (P ≤ 0·05). Furthermore, the PH group was characterised by a significantly lower concentration of TBARS in the lung tissue compared with rats fed the PM diet. The serum concentration of total cholesterol was subject to a significant decline in the PMc group with respect to the PH group, which resulted in significant differences in the HDL-cholesterol/total cholesterol profile between these groups (PMc>PH; P ≤ 0·05).
C, control; PL, diet supplemented with 10 % of root extract; PM, diet supplemented with 6·5 % of peel extract; PH, diet supplemented with 8 % of peel extract and 0·8 % of seed extract; PMc, diet supplemented with 2·5 % of leaf extract with 0·106 % of total phenolics; GPx, glutathione peroxidase; SOD, superoxide dismutase; ACW, antioxidant capacity of water-soluble substances in the plasma; ACL, antioxidant capacity of lipid-soluble substances in the plasma; TBARS, thiobarbituric acid-reactive substances.
a,b,c Mean values within a row with unlike superscript letters were significantly different (P ≤ 0·05).
* μmol ascorbic acid equivalents/ml of serum.
† μmol Trolox equivalents/ml of serum.
Discussion
The application of the preparations from whole roots, root peel, seeds and leaves of chicory that diversified the content and composition of the polyphenolic fraction in the diet had no significant effect on either the body weight or the feed conversion ratio. Body-weight gains of the experimental animals have also remained unaffected in toxicological surveys on diet supplementation with an ethanolic extract from chicory roots(Reference Schmidt, Nebojsa and Poulev18). The results of a large number of studies indicate that polyphenolic compounds, including phenolic acids, exhibit diversified activity in the bodies of humans and animals(Reference Fratianni, Tucci and De Palma1, Reference Couteau, McCartney and Gibson19, Reference Llorach, Tomas-Barberan and Ferreres20). In the discussed experiment, significant differences in coefficients of N digestibility were found only between the PM and PMc groups. This indicates that the high content of chicoric acid and glycosides in the extract from chicory leaves diminished the digestibility of total N from the diet compared with the root peel extract constituted exclusively by CQA. For other physiological parameters, including N retention, similar parameters of the small-intestine functioning and the fermentation process in the caecum and the colon did not confirm the aforementioned differences. A tendency could only be observed for restricting the process of intestinal digesta acidification by the polyphenolic fraction of chicory leaves.
Few in vivo experiments show that the pool of chlorogenic and DCQA absorbed in the small intestine affects the functioning of the cardiovascular system and peripheral tissues, whereas that metabolised by microbiota influences the ecosystem of the caecum and the colon(Reference Olthof, Hollman and Katan2). Investigations have demonstrated that after the ingestion of a DCQA-rich diet, those compounds both rapidly appear in the blood and are removed from it. This is due to the fact that methyl and glucuronic metabolites of those acids as well as DCQA themselves do appear in urine at the same time(Reference Yang, Meng and Yan21). In the discussed experiment, the chicory extracts applied in the diet had no negative effect on jejunal disaccharidase activity, which indicates undisturbed absorption of carbohydrates from the gastrointestinal tract. Activities of intestinal disaccharidases– maltase, lactase and sucrase – are linked with intestinal epithelium development and with the likely occurrence of damage to the epithelial tissue(Reference Chau, Sheu and Huang22).
It is estimated that about one-third of the ingested chlorogenic acid is absorbed in the small intestine of humans(Reference Choudhury, Srai and Debnam23). The remainder reaches the large intestine, where it is metabolised by bacteria. A few strains of bacteria belonging to Escherichia coli, Lactobacillus (e.g. L. gasseri) and Bifidobacterium (e.g. B. lactis) have been identified as colonising the gastrointestinal tract of humans and to be capable of synthesising esterase which hydrolyses chlorogenic acids(Reference Couteau, McCartney and Gibson19). In addition, chlorogenic and caffeic acids have been shown to exert strong inhibiting effects against the growth of selected strains of Streptococcus and enterobacteria, with their impacts in some cases being multiply stronger than those of ( − )-epicatechin and ( − )-epigallocatechin extracted from green tea(Reference Tsai, Tsai and Chien24). Having been released from chlorogenic acid by enzymes of the small intestine or bacterial esterase, caffeic acid may undergo further modifications, e.g. it may link with glucuronic acid, mainly in the liver, but also in the small and large intestine. Unfortunately, the linking of phenolic acids with glucuronic acid diminishes significantly their antioxidative properties(Reference Olthof, Hollman and Katan2). On the other hand, bacterial β-glucuronidase may re-hydrolyse binding with glucuronic acid, thus releasing bioactive compounds.
The reported experiment demonstrated the desirable, selective influence of the fructan–polyphenolic preparations on microbial enzymatic activity in the caecum and faeces of rats. The phenolic fraction was found not to inhibit the activity of the glycolytic enzymes released into the environment analysed in the caecal digesta, i.e. α- and β-galactosidase and α- and β-glucosidase. A contrary effect of chicory polyphenols was observed in the case of bacterial β-glucuronidase activity in the faeces and caecal digesta. It tended to diminish in the experimental groups, with the strongest inhibiting effect observed for the highest levels of diet supplementation with a mixture of MCQA and DCQA. It may be speculated that this was an additional effect of a dietary treatment with, besides fructans, a relatively high amount of the polyphenolic fraction. Some studies have demonstrated that phenolic acids are likely to exert a positive effect, synergistic with impacts of other biologically active compounds of the diet(Reference Svilaas, Sakhi and Andersen25). Also, in studies on biological properties of other classes of polyphenols, metabolism of the large intestine has been found to be positively affected by a prebiotic–phenolic mixture compared with supplements applied separately(Reference Zduńczyk, Juśkiewicz and Estrella26, Reference Aprikian, Duclos and Guyot27). The activity of microbiological β-glucuronidase is claimed to be a biomarker of an increased risk of neoplasm incidence(Reference Juśkiewicz, Wróblewska and Jarosławska16).
The greatest increase in the digesta bulk in the caecum was observed in rats fed the PH diet containing MCQA and DCQA at the level of 0·21 %, which confirms the earlier findings that polyphenols may increase digesta hydration and delay digesta passage, thus increasing their accumulation and, indirectly, increasing the mass of the intestinal wall(Reference Zduńczyk, Juśkiewicz and Estrella26, Reference Aprikian, Duclos and Guyot27). The extracts prepared from different parts of chicory did not trigger any significant changes in the total caecal SCFA concentration. In a study by Zduńczyk et al. (Reference Zduńczyk, Juśkiewicz and Estrella26), the presence of grapefruit polyphenols in inulin-containing diets was also observed not to change the caecal SCFA concentration in rats. In the reported experiment, only the diet with the highest level of MCQA and DCQA significantly diminished the concentration of propionic acid and increased the caecal acetic acid pool. The above changes in the caecal concentrations of SCFA were consistent with blood markers of the lipid profile of the rats from the PH group. Propionate is claimed to be involved in the cholesterol-lowering effect of fibres by impairing acetate utilisation, especially when cholesterol synthesis is activated to compensate for enhanced faecal losses of steroids(Reference Demigné, Morand and Levrat28).
A number of authors have reported that plants containing both prebiotic carbohydrates and a rich phenolic fraction demonstrate, apart from strong antioxidative properties, a positive effect on the lipid profile, including a decreased cholesterol concentration(Reference Zduńczyk, Juśkiewicz and Estrella26, Reference Aprikian, Duclos and Guyot27). A study with volunteers has confirmed the mild hypocholesterolaemic effect of an artichoke extract rich in 1,3-DCQA (cinarine), at the dosage of 500–1500 mg of cinarine/d(Reference Clifford29). In the discussed experiment, the expected favourable effect of the polyphenolic fraction on the glucose level and the lipid profile of the blood serum was not observed due to the analogous action of the fructan fraction, whose modulatory impact on lipid metabolism has already been well documented(Reference Rodriguez and Hadley6, Reference Juśkiewicz, Wróblewska and Jarosławska16). The lowest total cholesterol concentration and the highest value of the HDL-cholesterol profile in the PMc group may point to a more beneficial effect of the leaf extract compared with the extract prepared from chicory roots. It may, thus, be speculated that such an effect was due to compounds absent in the root extract, namely chicoric acid and/or polyphenolic glycosides.
Phenolic compounds are claimed to be capable of interrupting processes of chain auto-oxidation of free radicals(Reference Llorach, Tomas-Barberan and Ferreres20). Using the diphenylpicryl hydrazine∙ method, it has been demonstrated that the main components of an ethanolic extract from Cratoxylum formosum, i.e. chlorogenic acid, DCQA and ferulic acid, display similar antioxidative properties, and that the whole extract was a stronger scavenger of free radicals than model antioxidants, such as α-tocopherol and butylated hydroxytoluene(Reference Maisuthisakul, Pongsawatmanit and Gordon30). However, in another experiment, with the use of a LDL-cholesterol oxidation test conducted for preparations from different parts of artichoke obtained with two extraction methods, the antioxidative activity was not highly correlated with the content of total polyphenols in the extract(Reference Coinu, Carta and Urgeghe31). This, in turn, points to a varied antioxidative potential of different polyphenolic fractions or to a significant effect of the extraction method on the antioxidative properties of resultant preparations. The results obtained in the present study with respect to the TBARS level in the bodies of rats show that the content of chicory polyphenols in a diet affects the antioxidative status of the lungs – an organ being highly exposed to lipid peroxidation. Diet supplementation with a mixture of MCQA and DCQA originating from the extracts prepared from root peels and seeds of chicory at a level of 0·21 % diet as well as diet supplementation with the extract of leaves (0·11 % diet) considerably reduced the TBARS concentration in the lungs. Worthy of note is the fact that the results discussed herein refer to an experiment conducted with healthy rats, which additionally emphasises the considerable antioxidative potential in vivo of the polyphenolic fraction of chicory. In the discussed study, the experimental treatments had no effect on glutathione peroxidase and superoxide dismutase activities in the blood. In contrast, in the group with the medium level of diet supplementation with MCQA and DCQA, unexpected differences were observed in the values of ACW and ACL parameters, i.e. respectively the highest and the lowest value out of all groups examined. The tendencies observed were, however, not confirmed at the lower or higher level of the polyphenolic fraction in the diet. A number of authors have pointed to noticeable discrepancies in values of selected (superoxide dismutase, glutathione peroxidase, ACW and ACL) parameters characterising the antioxidative status of a body exposed to the oxidative stress(Reference Ugochukwu, Bagayoko and Antwi32, Reference Juśkiewicz, Zduńczyk and Jurgoński33). For this reason, a reliable evaluation of the effect of phytocompounds on the health status of the body should be based on a complex analysis of multiple metabolic markers of blood and peripheral tissues.
Conclusions
In the summary of the discussed experiment, it may be concluded that the applied addition of the polyphenolic fraction to diets containing prebiotic fructans did not diminish the positive effect of inulin and oligofructose on the ecosystem of the gastrointestinal tract and other functional parameters of the laboratory animals. An additional effect of diet supplementation with the extracts from chicory roots and seeds, especially at the highest level of supplementation with MCQA and DCQA reaching 0·21 % diet, induced beneficial changes in parameters of the oxidative status of the body and in bacterial β-glucuronidase activity in the faeces and caecal digesta. Some of the physiological parameters analysed indicate that increasing doses of the polyphenols in the diet may – to some extent – disturb metabolism in the distal section of the gastrointestinal tract, i.e. evoke excessive accumulation of hydrated intestinal digesta. Diet supplementation with an extract from chicory leaves containing considerable quantities of chicoric acid and polyphenolic glycosides, apart from chlorogenic acids, also triggered positive changes in the lipid profile of blood serum as well as deceleration of pro-oxidative processes in lung tissue. In contrast, no positive effect of the leaf extract was observed with respect to the activity of bacterial β-glucuronidase released into the environment and acidification of caecal digesta.
Acknowledgements
The authors declare no conflicts of interest and take responsibility for the integrity of the data and the accuracy of the analyses. J. J. and Z. Z. were involved in the conception of the study; B. K. and J. M. prepared the extracts and their chemical characteristics; J. J., E. Ż.-S. and A. J. were involved in the collection and assembly of the data and the analysis of the physiological response; J. J. and E. Ż.-S. prepared the manuscript and performed the statistical analyses. Critical revision of the text was completed by all the authors. This research received no specific grant from any funding agency in the public, commercial or not-for-profit sectors.