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Nutrition and Food Science Area. Faculty of Pharmacy, University of Valencia, Avda. Vicente Andrés Estellés s/n, 46100 - Burjassot, Valencia, Spain
Amparo Alegría
Nutrition and Food Science Area. Faculty of Pharmacy, University of Valencia, Avda. Vicente Andrés Estellés s/n, 46100 - Burjassot, Valencia, Spain
Reyes Barberá
Nutrition and Food Science Area. Faculty of Pharmacy, University of Valencia, Avda. Vicente Andrés Estellés s/n, 46100 - Burjassot, Valencia, Spain
María Jesús Lagarda
Nutrition and Food Science Area. Faculty of Pharmacy, University of Valencia, Avda. Vicente Andrés Estellés s/n, 46100 - Burjassot, Valencia, Spain
*Address all correspondence to: antonio.cilla@uv.es
1. Introduction
Epidemiological studies on the relationship between dietary habits and disease risk have shown that food has a direct impact on health. Indeed, our diet plays a significant role in health and well-being, since unbalanced nutrition or an inadequate diet is known to be a key risk factor for chronic age-related diseases [1]. An example that illustrates this fact is the protective effect of the so-called Mediterranean diet. The lower occurrence of cancer and cardiovascular disease in the population located around the Mediterranean sea has been linked to the dietary habits of the region, in which the components of the diet contain a wide array of molecules with antioxidant and antiinflammatory actions [2].
Many diseases with a strong dietary influence include oxidative damage as an initial event or in an early stage of disease progression [3]. In fact, Western diets (typically dense in fat and energy and low in fiber) are associated with disease risk [4]. Therefore, dietary modification, with a major focus on chronic age-related disease prevention through antioxidant intervention, could be a good and cost-effective strategy [5]. The intake of whole foods and/or new brand developed functional foods rich in antioxidants would be suitable for this purpose. In this sense, dietary antioxidants such as polyphenols, carotenoids and peptides, as well as other bioactive chemopreventive components such as fiber and phytosterols have been regarded to have low potency as bioactive compounds when compared to pharmaceutical drugs, but since they are ingested regularly and in significant amounts as part of the diet, they may have noticeable long-term physiological effects [6].
For decades, the beneficial role of antioxidants was related to the reduction of unwanted and uncontrolled production of reactive oxygen species (ROS), leading to a situation referred to as oxidative stress [7]. Nowadays, the term “antioxidant” has become ambiguous, since it has different connotations for distinct audiences. For instance, for biochemists and nutritionists, the term is related to the scavenging of metabolically generated ROS, while for food scientists the term implies use in retarding food oxidation or for the categorization of foods or substances according to in vitro assays of antioxidant capacity, such as the ORAC and TEAC tests [8]. The antioxidant values provided by these assays sometimes have been misinterpreted by both food producers and consumers due to the fact that health claims advertised on the package labeling are directly associated with benefits that include slowing of the aging process and decreasing the risk of chronic disease. Nevertheless, contemporary scientific evidence indicates that total antioxidant capacity measured by currently popular chemical assays may not reflect the actual activity in vivo, since none of them take biological processes such as bioavailability, uptake and metabolism into account [9]. Therefore, no in vitro assay that determines the antioxidant capacity of a nutritional product describes in vivo outcomes, and such testing should not be used to suggest such a connection. In this sense, it is currently recognized that the mechanisms of action of antioxidants in vivo might be far more complex than mere radical scavenging - involving interactions with specific proteins central to intracellular signaling cascades [10], and in the specific case of cancer cells there might be a direct antioxidant effect, antiproliferation and anti-survival action, the induction of cell cycle arrest, the induction of apoptosis, antiinflammatory effects and the inhibition of angiogenesis and metastasis [11].
In order to determine and verify the action of these bioactive compounds, it is clear that data from human intervention studies offer the reference standard and the highest scientific evidence considering the bioavailability and bioactivity of a food component, while in vitro methods are used as surrogates for prediction [12]. From a physiological perspective, food after consumption undergoes a gastrointestinal digestion process that may affect the native antioxidant potential of the complex mixture of bioactive compounds present in the food matrix before reaching the proximal intestine. In vitro methods which apply human simulated digestion models (including or not including colonic fermentation) are considered valuable and useful tools for the estimation of pre-absorptive events (i.e., stability, bioaccessibility) of different food components from distinct food sources, and also for determining the effect which processing may have upon food components bioavailability [13]. In addition, in vitro assays combining a simulated gastrointestinal digestion process and cell cultures as pre-clinical models can be useful for unraveling mechanisms of action and for projecting further in vivo assays [9]. Nevertheless, in most cases these in vitro studies are unrealistic, because they involve single compounds used at high concentrations (pharmacological and not dietary concentrations) far from the low micromolar or nanomolar concentrations detected in vivo, or use the bioactive compounds “as they are in food” versus the metabolites or derivatives considered to be the true bioactive compounds, over an extended period of time (up to 120 h). As a result, biological activity may be overestimated, since no account is taken of the possible transformation of these compounds during gastrointestinal digestion with or without colonic fermentation [6]. Likewise, the use of single or crude compounds instead of whole foods impedes the detection of synergistic and/or antagonistic actions among bioactive chemopreventive compounds [14, 15].
Taking this background together, and in order to obtain a more precise view of the in vivo situation, we propose the use of whole foods or related target bioactive constituents subjected to a human simulated gastrointestinal digestion including or not including colonic fermentation, depending on the nature of the studied compounds, in order to gain better insight from a nutritional/functional point of view of the chemopreventive action derived from foods and bioactive compounds in cell models of disease.
This review introduces the main features of the different in vitro gastrointestinal digestion (solubility and dialysis) and colonic fermentation procedures (batch, continuous and continuous with immobilized feces) for studying the bioaccessibility and further bioavailability and bioactivity of nutrients and bioactive compounds. It also includes a definition of the terms: bioavailability including bioaccessibility and bioactivity. Likewise, the main advantages and disadvantages of these in vitro methods versus in vivo approaches, the improvement of these models with the inclusion of cell lines, and a short comment on the main effects that digestion and/or fermentation have on bioactive compounds are included. On the other hand, a short description is provided of the studies involving the use of human simulated gastrointestinal digestion and/or colonic fermentation procedures, and of the subsequent bioactivity-guided assays with cell line models.
Bioavailability is a key concept for nutritional effectiveness, irrespective of the type of food considered (functional or otherwise). Only certain amounts of all nutrients or bioactive compounds are available for use in physiological functions or for storage.
The term bioavailability has several working conditions. From the nutritional point of view, bioavailability is defined as the proportion of a nutrient or bioactive compound can be used for normal physiological functions [16]. This term in turn includes two additional terms: bioaccessibility and bioactivity. Bioaccessibility has been defined as the fraction of a compound that is released from its food matrix in the gastrointestinal tract and thus becomes available for intestinal absorption. Bioaccessibility includes the sequence of events that take place during food digestion for transformation into potentially bioaccessible material, absorption/assimilation through epithelial tissue and pre-systemic metabolism. Bioactivity in turn includes events linked to how the bioactive compound is transported and reaches the target tissue, how it interacts with biomolecules, the metabolism or biotransformation it may undergo, and the generation of biomarkers and the physiologic responses it causes [12]. Depending on the in vitro method used, evaluation is made of bioaccessibility and/or bioactivity.
In vitro methods have been developed to simulate the physiological conditions and the sequence of events that occur during digestion in the human gastrointestinal tract. In a first step, simulated gastrointestinal digestion (gastric and intestinal stages, and in some cases a salivary stage) is applied to homogenized foods or isolated bioactive compounds in a closed system, with determination of the soluble component fraction obtained by centrifugation or dialysis of soluble components across a semipermeable membrane (bioaccessible fraction). Simulated gastrointestinal digestion can be performed with static models where the products of digestion remain largely immobile and do not mimic physical processes such as shear, mixing, hydration. Dynamic models can also be used, with gradual modifications in pH and enzymes, and removal of the dialyzed components – thereby better simulating the actual in vivo situation. All these systems evaluate the aforementioned term “bioaccessibility”, and can be used to establish trends in relative bioaccessibility.
The principal requirement for successfully conducting experimental studies of this kind is to achieve conditions which are similar to the in vivo conditions. Temperature, shaking or agitation, and the chemical and enzymatic composition of saliva, gastric juice, duodenal and bile juice are all relevant aspects in these studies. Interactions with other food components must also be taken into account, since they can influence the efficiency of digestion [12, 17]. A recent overview of the different in vitro digestion models, sample conditions and enzymes used has been published by Hur et al. [13]. En lipophilic compounds such as carotenoids and phytosterols, it is necessary to form mixed micelles in the duodenal stage through the action of bile salts, phospholipases and colipase. This allows the compounds to form part of the micelles, where they remain until uptake by the enterocytes [18]. In the case of lycopene, during digestion isomerization of trans-lycopene may occur with the disadvantage that trans-isomers are less soluble in bile acid micelles [19]. Salivary and gastric digestion exert no substantial effect on major phenolic compounds. However, polyphenols are highly sensitivity to the mild alkaline conditions in pancreatic digestion, and a good proportion of these compounds can be transformed into other unknown and/or undetected forms [20].
Bioactive compounds such as dietary fiber, carotenoids, polyphenols and phytosterols undergo very limited absorption, and may experience important modifications as a result of actions on the part of the intestinal microbiota. Small intestine in vitro models are devoid of intestinal microbes, and are designed to only replicate digestion and absorption processes; as a result, they are unable to provide information on intestinal fermentation processes. The incorporation of colonic/large intestine fermentation offers a better approximation to the in vivo situation, and allows us to study the effect/interaction between these compounds and the intestinal microbiota.
In vitro colonic fermentation models are characterized by the inoculation of single or multiple chemostats with fecal microbiota (of rat or human origin) and operated under physiological temperature, pH and anaerobic conditions. There are two types of colonic fermentation models: batch culture and continuous cultures. Batch culture describes the growth of pure or mixed bacterial suspensions in a carefully selected medium without the further addition of nutrients in closed systems using sealed bottles or reactors containing suspensions of fecal material under anaerobic conditions. The advantages of batch fermentation are that the technique is inexpensive, easy to set up, and allows large number of substrates of fecal samples to be tested. However, these models have their weakness in microbiological control and the need to be of short duration in order to avoid the selection of non-representative microbial populations. The technique is useful for fermentation studies, for the investigation of metabolic profiles of short chain fatty acids arising from the active metabolism of dietary compounds by the gut microbiota, and especially for substrate digestion evaluation studies [21, 22]. Several of the publications in this field are based on a European interlaboratory study for estimation of the fermentability of dietary fiber in vitro [23].
Continuous cultures allow us to control the rate and composition of nutrient feed, bacterial metabolism and the environmental conditions. These models simulate proximal (single-state models) or proximal, transverse and distal colonic regions (multistage models). Continuous cultures are used for performing long-term studies, and substrate replenishment and toxic product removal are facilitated - thereby mimicking the conditions found in vivo. The most variable factor in these models is the technique used for fecal inoculation. The use of liquid fecal suspension as inoculum, where the bacterial populations are in the free-cell state, produces rapid washout of less competitive bacteria; as a result, the operation time is less than four weeks. The formation of fecal beads from the immobilization of fecal microbiota in a porous polysaccharide matrix allows release of the microbiota into the culture medium, with better reproduction of the in vivo flora and longer fermentation times [21, 22].
Artificial continuous models including host functions/human digestive functions have been developed. Models of this kind control peristaltic movement, pH and gastrointestinal secretions. The SHIME model (Simulated Human Intestinal Microbial Ecosystem) comprises a 5-step multi-chamber reactor simulating the duodenum and jejunum, ileum, cecum and the ascending colon, transverse colon and descending colon [24]. In turn, TIM-1 is an intestinal model of the stomach and small intestine, while TIM-2 is a proximal colon simulator model developed by TNO (Netherlands Organization for Applied Scientific Research). These models have been validated based on human and animal data [25]. They incorporate some host functions; however, they do not reproduce immune modulating and neuroendocrine responses. A remaining challenge is the difficulty of establishing a representative human gut microbiota in vitro. Other difficulties are the availability of the system, its cost, the prolonged time involved, its laboriousness, the use of large working volumes, and long residence times.
Combined systems that include the fractions obtained from simulated human digestion (gastrointestinal and/or colonic fermentation) and the incorporation of cell culture-based models allow us to evaluate bioaccessibility (estimate the amount of bioactive compounds assimilated from the bioaccessible fraction by cell culture) and to conduct bioactivity studies. The Caco-2 cell model is the most widely used and validated intestinal epithelium or human colon carcinoma cell model. Although colonic in origin, Caco-2 cells undergo spontaneous differentiation in cell culture to form a monolayer of well-polarized cells at confluence, showing many of the functional and morphological properties of mature human enterocytes (with the formation of microvilli on the brush border membrane, tight intercellular junctions and the excretion of brush border-associated enzymes) [26]. However it must be mentioned that this cell line differs in some aspects from in vivo conditions. For example, it does not reproduce the different populations of cells in the gut, such as goblet, Paneth and crypt cells, which are less organized and therefore leakier. Likewise, the model lacks regulatory control by neuroendocrine cells and through the blood [27].
The advantage of these systems versus those which only evaluate the influence of digestion is their greater similarity to the in vivo conditions. The combination of in vitro human intestinal cell models with in vitro digestion models in turn creates an advanced in vitro model system where samples obtained from host responses lacking in in vitro digestion models can be directly applied to monolayer cell models for host function studies [21].
3. Bioactivity of digested/fermented foods or related target bioactive compounds in cell lines
The chemopreventive properties of bioactive compounds have been investigated in cultured cells exposed to individual compounds. However, gut epithelial cells are more likely to be exposed to complex food matrixes containing mixtures of bioactive and antioxidant in vivo compounds [6]. In addition, food matrixes undergo a digestion process that may affect the structure and properties of the bioactive compounds. Therefore, the in vitro protective effects of antioxidant bioactive compounds do not necessarily reflect in vivo chemoprotection, which is more likely due to the combined effects of all the bioactive components present in the food [28].
A potential cell culture model for cancer or cardiovascular chemoprevention research involving dietary antioxidants (polyphenols, carotenoids and peptides) and other bioactive chemopreventive components such as phytosterols, should include some of the proposed mechanisms of action: inhibition of cell proliferation, induction of tumor suppressor gene expression, induction of cell cycle arrest, induction of apoptosis, antioxidant enzyme induction, and enhanced detoxification, antiinflammatory activities and the inhibition of cholesterol absorption [9, 15, 29, 30]. In addition, other mechanisms of chemoprevention could involve protection against genotoxic compounds or reactive oxygen species [31].
It recently has been stated that the measurement of cellular bioactivity of food samples coupled to in vitro digestion can provide information close to the real-life physiological situation [32]. In this sense, we surveyed more than 30 studies conducted in the past 10 years, involving human simulated gastrointestinal digestion and/or colonic fermentation procedures and subsequent bioactivity-guided assays with cell line models. These studies are presented in Tables 1, 2 and 3, which correspond to the mechanism of action related to chemoprevention of digested, fermented or digested plus fermented foods or bioactive constituents in cell lines, respectively.
The chemopreventive effect of digested foods or bioactive constituents in cell lines is summarized in Table 1. From the 22 studies surveyed, and according to the digestion method used, it can be seen that most of them involve solubility (n = 17) versus dialysis (n = 5). Samples used are preferably of vegetal origin (n = 15), the target compounds responsible for the chemopreventive action being polyphenols, antioxidants (in general), antioxidant peptides, lycopene and phytosterols. Furthermore, these compounds are mainly studied in colon-derived cells (as a cancer model when not differentiated, or as an intestinal epithelial model when differentiated). Concentrations tested are physiologically achievable in colon cells, since the bioaccessible fractions obtained after digestion are considered to be fractions that can pass through the stomach and small intestine reaching the colon, where they can exert antioxidant activity in situ [33]. In addition, polyphenols are studied in neuronal cells, liver-derived cells and lymphocytes. In the case of neuronal cells, the concentrations used (0-6 µM polyphenols) are similar to those reported for dietary polyphenolic-derived metabolites found in plasma (0-4 µM) [34], but for lymphocytes and liver, the concentrations are unknown or higher than expected in vivo, respectively. Another aspect to bear in mind is the time of cell exposure to the digested food or bioactive constituents. The range found in these studies is from 30 min to 120 h (this latter timepoint not being expectable from a physiological standpoint).
Bioactive compounds of digested foods present four different but in some cases complementary modes of action: (1) inhibition of cholesterol absorption (phytosterols), and (2) antiproliferative, (3) cytoprotective and (4) antiinflammatory activities (polyphenols and general antioxidants).
The inhibition of cholesterol absorption has been reported to be mainly due to competition between phytosterols and cholesterol for incorporation to the micelles as a previous step before absorption by the intestinal epithelial cells [35].
Antiproliferative activity has been linked to cell growth inhibition associated to polyphenols [28, 32, 36-38] and lycopene [39], which is mainly regulated by two mechanisms: cell-cycle arrest and apoptosis induction. The cell cycle can be halted at different phases: G0/G1 with down-regulation of cyclin D1 [39], S with down-regulation of cyclins D1 and B1 [28, 37] and G2/M [36]. Apoptosis induction in turn occurs as a result of caspase-3 induction and down-regulation of the anti-apoptotic proteins Bcl-2 and Bcl-xL [39].
The cytoprotective effect of polyphenols, peptides and antioxidants against induced oxidative stress is related to the preservation of cell viability [40-47], an increase in the activity of antioxidant enzymes (such as catalase, glutathione reductase or glutathione peroxidase) [41, 43, 47, 48], the prevention of reduced glutathione (GSH) depletion [46, 47, 49], a decrease in intracellular ROS content [46, 50, 51], the maintenance of correct cell cycle progression [41, 43, 47, 52], the prevention of apoptosis [43], and the prevention of DNA damage [42, 51, 52].
The antiinflammatory action of peptides and polyphenols is derived from the decrease in the release of proinflammatory cytokines such as IL-8 when cells are stimulated with stressors such as H202 or TNFα [53, 54].
Studies on the chemopreventive effect of foods or isolated bioactive constituents following colonic fermentation or gastrointestinal digestion plus colonic fermentation in cell lines are shown in Tables 2 and 3, respectively. The colonic fermentation procedure used in these assays has always been a batch model, except for one study combining batch and dynamic fermentation. In turn, when gastrointestinal digestion is involved, dialysis has been the method used. Foods of plant origin rich in fiber, and short chain fatty acids (mainly butyrate) and polyphenols as the target compounds have been used in such studies. The use of colon-derived cell lines is common in these assays, which have been performed using physiologically relevant concentrations and time periods of exposure of samples to cells ranging between 24 h and 72 h.
The mechanism of action underlying the treatment of cells with colonic fermented foods or isolated bioactive constituents (see Table 2) mainly comprises antiproliferative activity (i) and/or cytoprotective action (ii). In the first case, antiproliferative activity (i) has been attributed to cell growth inhibition [55-59], mainly due to apoptosis induction [58-59] and/or the up-regulation of genes involved in cell cycle arrest (p21) and apoptosis (WNT2B) [59]. Studies referred to a cytoprotective effect against oxidative damage (ii) in turn have been linked to the prevention of DNA damage [55, 56] and to the induction of antioxidant enzymes such as glutathione-S-transferase (GST) [56].
The bioactivity observed with the incubation of cells lines with foods or isolated bioactive constituents following gastrointestinal digestion plus colonic fermentation (see Table 3) is derived from antiproliferative activity (i) regulated by cell growth inhibition [60-62], cell cycle arrest [60] and/or apoptosis induction [60, 62], or by a cytoprotective effect against induced oxidative stress (ii) as a result of preservation of cell viability [63], protection against DNA damage [31, 61, 63] and/or induction of antioxidant enzymes such as CAT, GST and sulfotransferase (SULT2B1) [31].
From the data here reviewed in disease cell models, it can be concluded that gastrointestinal digestion/colonic fermentation applied to whole foods or isolated bioactive constituents may have potential health benefits derived from cell growth inhibition through the induction of cell-cycle arrest and/or apoptosis, cytoprotection against induced oxidative stress, antiinflammatory activity and the reduction of cholesterol absorption.
Studies conducted with single bioactive compounds are unrealistic from a nutritional and physiological point of view, since they do not take into account physicochemical changes during digestion and possible synergistic activities. Thus, a combined model of human simulated digestion including or not including colonic fermentation (depending on the nature of the studied compounds) with cell lines should be carried out if in vitro bioactivity assays with whole foods or bioactive chemopreventive compounds for the prevention of oxidative stress-related diseases are planned.
Although digested/fermented bioactive compounds appear as promising chemopreventive agents, our understanding of the molecular and biochemical pathways behind their mechanism of action is still limited, and further studies are warranted. In addition, the need for harmonization of the in vitro methods: (i) conditions of the gastrointestinal procedure, (ii) cell line used, (iii) concentrations of bioactive compounds used (usually much higher than those achievable in the human body when the digestion process is not considered), and (iv) time of cell exposure to the bioactive compounds (more than 24 h is unlikely to occur in vivo), should be considered for improved study designs more similar to the in vivo situation and for allowing comparisons of results among laboratories. This task is currently being carried out at European level within the project “Improving health properties of food by sharing our knowledge on the digestive process (INFOGEST) (2011-2015) (FAO COST Action FA 1005) (http://www.cost-infogest.eu/ABOUT-Infogest)”.
Sample(Target compound/s)
Cell type
Cell treatment(Concentrations and time)
Cellular mechanism
References
Gastrointestinal digestion (dialysis)
(Polyphenols)
Chokeberry juice
Caco-2 (human colon carcinoma)
85 to 220 (µM total polyphenols) 2 h a day for a 4-day period
Cell growth inhibition Viability decrease Cell cycle arrest at G2/M phase Up-regulation of tumor suppression gene CEACAM1
Bermúdez-Soto et al. (2007) [36]
Raspberries
HT29, Caco-2 and HT115 (human colon carcinoma)
3.125 to 50 (µg/mL) 24 h
Prevention of H2O2 (75µM/5min)-induced DNA damage and decrease in G1 phase of cell cycle (HT29 cells) No effect on epithelial integrity (Caco-2 cells) Inhibition of colon cancer cell invasion (HT115 cells)
Coates et al. (2007) [52]
Green tea
Differentiated PC12 (model of neuronal cells)
0.3-10 µg/mL (for H2O2) and 0.03-0.125 µg/mL (for Aβ(1-42)) Pretreatment 24 h and stressed 24 h
Protection against H2O2 and Aβ(1-42) induced cytotoxicity (only at low concentrations)
Okello et al. (2011) [44]
Blackberry (Rubus sp.)
SK-N-MC (neuroblastoma cells)
1.5-6 µM total polyphenols 24 h
Preservation of cell viability against H2O2 (300 µM- 24 h) –induced oxidative stress (not related to modulation of ROS nor GSH levels)
Tavares et al. (2012a) [45]
Table 1.
Mechanisms involved in the chemopreventive effect of in vitro digested foods or bioactive constituents in cell lines.
The in vitro simulation of the conditions of gastrointestinal digestion represents an alternative to in vivo studies for evaluating the bioavailability and/or functionality of bioactive components of foods. In vitro studies do not replace in vivo studies; rather, both complement each other. In vitro methods need to be improved and validated with more in vivo studies. Thus, caution is mandatory when attempting to extrapolate observations obtained in vitro in cell line studies to humans.
Sample(Target compound/s)
Cell type
Cell treatment(Concentrations and time)
Cellular mechanism
References
Wild blackberry species
SK-N-MC (neuroblastoma cells)
0-6 µM total polyphenols 24 h
Preservation of cell viability and mitochondrial membrane potential against H2O2 (300 µM -24 h)-induced oxidative stress Decrease of intracellular ROS against H2O2 (200 µM -1 h)-induced oxidative stress (only R. brigantines) Prevention of GSH depletion against H2O2 (300 µM -24 h)-induced oxidative stress Induction of caspase 3/7 activity against H2O2 (300 µM -24 h)-induced oxidative stress (preconditioning effect)
Tavares et al. (2012b) [46]
Gastrointestinal digestion (solubility)
(Polyphenols)
Fruit beverages with/without milk and/or iron
Caco-2 (human colon carcinoma)
2%, 5% and 7.5% (v/v) in culture medium (3.4-22.7 mg/mL total polyphenols) 4 hours-4 days or 24 h
Cell growth inhibition (no clear dose-response) Cell cycle arrest at S phase (7.5%) Down-regulation of cyclins D1 and B1 No apoptosis (cytostatic effect)
Cilla et al. (2009) [28]
Zinc-fortified fruit beverages with/without iron and/or milk
Caco-2 and HT-29 (human colon carcinoma)
7.5% (v/v) in culture medium (~50 µM total polyphenols) 24 h
Cell growth inhibition (without citotoxicity) Cell cycle arrest at S phase No apoptosis and resumption of cell cycle after digest removal (cytostatic effect)
Cilla et al. (2010) [37]
Fruit juices enriched with pine bark extract
Caco-2 (human colon carcinoma)
4% (v/v) in culture medium 24-120 h
Cell growth inhibition
Frontela-Saseta et al. (2011) [38]
Table 1.
(continued-I).
Sample(Target compound/s)
Cell type
Cell treatment(Concentrations and time)
Cellular mechanism
References
Feijoada-traditional Brazilian meal
HepG2 (human liver cancer cells)
10-100 mg/mL 72 h (antiproliferation) and 1 h (antioxidant)
PBL (peripheral blood lymphocytes) and Differentitated Caco-2 (model of intestinal epithelium)
1:10 (v/v) in culture medium. Stressors (H2O2 2 mM and TNFα 100 µg/mL) Co-incubation 24 h or pre-incubation 3h then stress 24 h
PBL: significant decrease in IL-8 release when co-incubation with H2O2 and pre-incubation prior H202 and TNFα Caco-2: significant decrease in IL-8 release only when co-incubation with TNFα
Chohan et al. (2012) [54]
(Antioxidants)
Fruit beverages with/without milk and/or iron/zinc
Differentiated Caco-2 (model of intestinal epithelia)
1:1 (v/v) in culture medium
Preservation of cell viability No alteration of SOD
Cilla et al. (2008) [40]
Fruit beverages with/without milk or CPPs
Differentiated Caco-2 (model of intestinal epithelia)
1:1 (v/v) in culture medium or CPPs (1.4 mg/mL)
Preservation of cell viability (only fruit beverages)
Laparra et al. (2008) [41]
Beef patties enriched with sage and oregano
Caco-2 (human colon carcinoma)
10-100% (v/v) 24 h
Increase in cell viability at low concentrations (20-40%) but slight decrease at high concentrations (80-100%) Increase in GSH (only sage-enriched samples at 10%) Protection against H202 (200 µM/1h)-induced GSH depletion (at 10%)
Ryan et al. (2009) [49]
Table 1.
(continued-II).
Sample(Target compound/s)
Cell type
Cell treatment(Concentrations and time)
Cellular mechanism
References
Ellagic acid-, lutein- or sesamol-enriched meat patties
Caco-2 (human colon carcinoma)
0-20% (v/v) in culture medium 24 h
Viability maintenance against H202 (500 µM/1h)-induced stress Prevention of H202 (50 µM/30 min)-induced DNA damage
Daly et al. (2010) [42]
Pacific hake fish protein hydrolysates
Caco-2 (human colon carcinoma)
0.625-5 mg/mL 2 h
Inhibition (at non cytotoxic doses) of intracellular oxidation induced by AAPH (50 µM/1-2 h)
Samaranayaka et al. (2010) [50]
Human breast milk
Co-culture of Caco-2 BBE and HT29-MTX (model of human intestinal mucosa)
1:3 (v/v) in culture medium 30 min
Decrease of H202 (1 mM/30 min)-induced ROS Prevention of H202 (500 µM/30 min)-induced DNA damage
Yao et al. (2010) [51]
Fruit beverages with/without milk and/or iron/zinc
Differentiated Caco-2 (model of intestinal epithelia)
1:1 (v/v) in culture medium Pre-incubation 24 h then stressed 2h with H202 5 mM
Preservation of cell viability Increase in GSH-Rd activity (only Fe or Zn with/without milk samples) Prevention of G1 cell cycle phase decrease induced by H202 Prevention of apoptosis (caspase-3) induced by H202
Cilla et al. (2011) [43]
Purified milk hydrolysate peptide fraction from digested human milk
Caco-2 and FHs 74 int (human colon carcinoma and primary fetal enterocytes)
0.31-1.25 g/L (peptide) and 150 µM (tryptophan) 2 h (peptide) and 1-12 h (tryptophan)
Exacerbation of AAPH (50 µM/1-2 h)-induced oxidative stress (peptide) Up-regulation of Nrf-2 and subsequent up-regulation of GSH-Px2 gene as adaptive response to stress (tryptophan)
Elisia et al. (2011) [48]
Table 1.
(continued-III).
Sample(Target compound/s)
Cell type
Cell treatment(Concentrations and time)
Cellular mechanism
References
CPPs from digested cow’s skimmed milk
Differentiated Caco-2 (model of intestinal epithelia)
1, 2 and 3 mg/mL Pre-incubation 24 h then stressed 2h with H202 5 mM
Preservation of cell viability Increase in GSH content and induction of CAT activity Decrease in lipid peroxidation Maintenance of correct cell cycle progression
García-Nebot et al. (2011) [47]
Purified hen egg yolk-derived phosvitin phosphopeptides
Differentiated Caco-2 (model of intestinal epithelia)
0.05-0.5 mg/mL 2 h
Reduced IL-8 secretion in H202 (1 mM/6 h)-induced oxidative stress
Young et al. (2011) [53]
(Lycopene)
Tomatoes
HT29 and HCT-116 (human colon carcinoma)
20-100 mL/L 24 h
Cell growth inhibition Cell cycle arrest at G0-G1 phase and apoptosis induction (caspase-3) Down-regulation of cyclin D1 and anti-apoptotic proteins Bcl-2 and Bcl-xL
Palozza et al. (2011) [39]
(Phytosterols)
Orange juice enriched with fat-free phytosterols
Differentiated Caco-2 (model of intestinal epithelia)
2 mL test medium/well 4 h
Reduced micellarization of cholesterol Decrease in cholesterol accumulation by Caco-2 cells
Induction of antioxidant enzymes (CAT and GST) Up-regulation of genes CAT, GSTP1 and SULT2B1 Prevention of H202 (75 µM/5 min)-induced DNA damage
Stein et al. (2010) [31]
(SCFA and polyphenols)
Bread
HT29 (human colon carcinoma)
2.5-5% (v/v) in culture medium 24-72 h
Cell growth inhibition Prevention of H202 (75 µM/5 min)-induced DNA damage
Lux et al. (2011) [61]
(butyrate)
Bread
LT97 (human colon adenoma)
5-20% (v/v) in culture medium 24-72 h
Up-regulation of genes from DNA repair, biotransformation, differentiation and apoptosis Increase in GST activity, GSH content and AP activity (differentiation) Cell growth inhibition Apoptosis induction (caspase-3)
Schölrmann et al. (2011) [62]
Table 3.
Mechanisms involved in the chemopreventive effect of in vitro digested (dialysis) plus colonic fermented (batch) foods or bioactive constituents in cell lines.
This work was partially supported by Consolider Fun-C-Food CSD2007-00063 and the Generalitat Valenciana (ACOMP 2011/195).
References
1.MillenB. E.QuatromoniP. A.PencinaM.KimokotiR.Nam-HB.CobainS.KozakW.AppaglieseD. P.OrdovasJ.D’AgostinoR. B.2005Unique dietary patterns and chronic disease risk profiles of adult men: The Framinghan nutrition studiesJ. Am. Diet. Assoc.10517231734
2.PuawelsE. K. J.2011The protective effect of the Mediterranean diet: focus on cancer and cardiovascular riskMed. Princ. Pract.20103111
3.ValkoM.LeibfritzD.MoncolJ.CroninM. T.MazurM.TelserJ.2007Free radicals and antioxidants in normal physiological functions and human disease. Int. J. Biochem. Cell Biol.394484
4.JohanssonI.NilssonL.StegmayrB.BomanK.HallmansG.WinkvistA.2012Associations among 25-year trends in diet, cholesterol and BMI from 140,000 observations in men and women in Northern SwedenNutr. J.11140
5.BruceW. R.GiaccaA.MedlineA.2000Possible mechanisms relating diet and risk of colon cancerCancer Epidemiol. Biomarkers Prev.912711279
6.EspínJ. C.García-ConesaM. T.Tomás-BarberánF. A.2007Nutraceuticals: facts and fictionPhytochemistry6829863008
7.HolstB.WilliamsonG.2008Nutrients and phytochemicals: from bioavailability to bioefficacy beyond antioxidantsCurr. Opin. Biotechnol.197382
8.FinleyJ. W.KongN.-A.HintzeK. J.JefferyE. H.JiL. L.LeiX. G.2011Antioxidants in foods: state of the science important to the food industryJ. Agric. Food Chem5968376846
10.StevensonD. E.HurstR. D.2007Polyphenolic phytochemicals- just antioxidants or much more?Cell. Mol. Life Sci.6429002916
11.RamosS.2008Cancer chemoprevention and chemotherapy: dietary polyphenols and signaling pathwaysMol. Nutr. Food Res.52507526
12.Fernández-GarcíaE.Carvajal-LéridaI.Pérez-GálvezA.2009In vitro bioaccessibility assessment as a prediction tool of nutritional efficiencyNutr. Res.29751760
13.HurS. J.LimB. O.DeckerE. A.Mc ClementsD. J.2011In vitro human digestion models for food applicationsFood Chem.125112
14.LiuR. H.2003Health benefits of fruit and vegetables are from additive and synergistic combinations of phytochemicalsAm. J. Clin. Nutr.78517S520S
15.de KokT. M.van BredaS. G.MansonM. M.2008Mechanisms of combined action of different chemopreventive dietary compounds: a review.Eur. J. Nutr.475159
16.Fairweather-TaitS. J.1993Bioavailability of nutrients. Macrae R, Robinson RK, Sadler MJ, editors. Encyclopaedia of food science, food technology and nutrition. London: Academic Press.384388
17.EkmekciogluC.2002A physiological approach for preparing and conducting intestinal bioavailbility studies using experimental systemsFood Chem.76225230
18.YonekuraL.NagaoA.2007Intestinal absorption of dietary carotenoids. Mol. Nutr. Food Res.51107115
19.ParadaJ.AguileraJ. M.2007Food microstructure affects the bioavailability of several nutrientsJ. Food Sci.72R 21R32
20.Bermúdez-SotoM. J.Tomás-BarberánF. A.García-ConesaM. T.2007Stability of polyphenols in chokeberry (Aronia melanocarpa) subjected to in vitro gastric and pancreatic digestionFood Chem.102865874
21.PayneA. N.ZihlerA.ChassardC.LacroixC.2012Advances and perspectives in in vitro human gut fermentation modelingTrends Biotech.301725
22.MacfarlaneG. T.MacfarlaneS.2007Models for intestinal fermentation: association between food components, delivery sustems, bioavailability and functional interactions in the gutCurr. Opin. Biotechnol.18156162
23.BarryB. J. L.HoeblerC.MacfarlaneG. T.MacfarlaneS.MathersJ. C.ReedK. A.MortensenP. B.NorgaardI.RowlandI. R.RumneyC. J.1995Estimation of the fermentability of dietary fibre in vitro: a European interlaboratory studyBr. J. Nutr.74303322
24.MollyK.WoestyneM. V.VerstraeteW.1993Development of a 5-step multi-chamber reactor as a simulation of the human intestinal microbial ecosystemAppl. Microbiol. Biotechnol.39254258
25.MinekusM.MarteauP.HavenaarR.Huis in’t VeldJ. H. J.1995A multi compartmental dynamic computer-controlled model simulating the stomach and small intestineATLA.23197209
26.PintoM.Robine-LeonS.AppayM. D.KedingerM.TriadouN.DussaulxE.LacroixB.Simon-AssmannP.HaffenK.FoghJ.ZweibaumA.1983Enterocyte-like differentiation and polarization of the human colon carcinoma cell line Caco-2 in cultureBiol. Cell47323330
27.EkmekciogluC.PomazalK.SteffanI.SchweigerB.MarktlW.1999Calcium transport from mineral waters across Caco-2 cellsJ. Agric. Food Chem.4725942599
28.CillaA.González-SarríasA.Tomás-BarberánF. A.EspínJ. C.BarberáR.2009Availability of polyphenols in fruit beverages subjected to in vitro gastrointestinal digestión and their effects on proliferation, cell-cycle and apoptosis in human colon cancer Caco-2 cellsFood Chem.114813820
29.BradfordP. G.AwadA. B.2010Modulation of signal transduction in cancer cells by phytosterolsBiofactors36241247
30.BrüllF.MensikR. P.PlatJ.2009Plant sterols: functional lipids in immune function and inflammation?Clin Lipidol.4355365
31.SteinK.BorowickiA.ScharlauD.GleiM.2010Fermented wheat aleurone induces enzymes involved in detoxification of carcionogens and in antioxidative defence in human colon cellsBr. J. Nutr.10411011111
32.Kremer-FallerA. N.FialhoE.LiuR. H.2012Cellular antioxidant activity of Feijoada whole meal coupled with an in vitro digestionJ. Agric. Food Chem.6048264832
33.HalliwellB.RafterJ.JennerA.2005Health promotion by flavonoids, tocopherols, tocotrienols, and other phenols: direct or indirect effects? Antioxidant or not?Am. J. Clin. Nutr.81268S276S
34.ManachC.WilliamsonG.MorandC.ScalbertA.RemesyC.2005Bioavailability and bioefficacy of polyphenols in humans. I. Review of 97 bioavailability studiesAm. J. Clin. Nutr.81230S242S
35.BohnT.TianQ.ChitchumroonchokchaiC.FaillaM. L.SchwartzS. J.CotterR.WaksmanJ. A.2007Supplementation of test meals with fat-free phytosterol products can reduce cholesterol micellarization during simulated digestion and cholesterol accumulation by Caco-2 cells. J. Agric. Food Chem.55267272
36.MJBermúdez-SotoLarrosa. M.García-CantalejoJ. M.EspínJ. C.Tomás-BarberánF. A.García-ConesaM. T.2007Up-regulation of tumor supresor carcinoembryonic antigen-related cell adhesión molecule 1 in human colon cancer Caco-2 cells following repetitive exposure to dietery levels of a polyphenol-rich chokeberry juiceJ. Nutr. Biochem.18259271
37.CillaA.MJLagardaBarberá. R.RomeroF.2010Polyphenolic profile and antiproliferative activity of bioaccessible fractions of zinc-fortified fruit beverages in human colon cancer cell linesNutr. Hosp.25561571
38.Frontela-SasetaC.López-NicolásR.González-BermúdezC. A.Peso-EcharriP.Ros-BerruezoG.Martínez-GraciáC.CanalliR.VirgiliF.2011Evaluation of antioxidant activity and antiproliferative effect of fruit juices enriched with Pycnogenol® in colon carcinoma cells. The effect of in vitro gastrointestinal digestionPhytoter. Res.2518701875
39.PalozzaP.SeriniS.BonisegnaA.BellovinoD.LucariniM.MonastraG.GaetaniS.2007The growth-inhibitory effects of tomatoes digested in vitro in colon adenocarcinoma cells occur through down regulation of cyclin D1, Bcl-2 and Bcl-xLBr. J. Nutr.98789795
40.CillaA.LaparraJ. M.AlegríaA.BarberáR.FarréR.2008Antioxidant effect derived from bioaccessible fractions of fruit beverages against H2O2-induced oxidative stress in Caco-2 cellsFood Chem.10611801187
41.LaparraJ. M.AlegríaA.BarberáR.FarréR.2008Antioxidant effect of casein phosphopeptides compared with fruit beverages supplemented with skimmed milk against H202-induced oxidative stress in Caco-2 cellsFood Res. Int.41773779
42.DalyT.RyanE.AherneS. A.O’GradyM. N.HayesJ.AllenP.KerryJ. P.O’BrienN. M.2010Bioactivity of ellagic acis-, lutein- or sesamol-enriched meat patties assessed using an in vitro digestion in Caco-2 cell model systemFood Res. Int.43753760
43.CillaA.LaparraJ. M.AlegríaA.BarberáR.2011Mineral and/or milk supplementation of fruit beverages helps in the prevention of H202-induced oxidative stress in Caco-2 cellsNutr. Hosp.26614621
44.OkelloE. J.Mc DougallG. J.KumarS.SealC. J.2011In vitro protective effects of colon-available extract of Camellia sinensis (tea) against hydrogen peroxide and beta-amyloid (Aβ(1-42)) induced cytotoxicity in differentiated PC12 cellsPhytomedicine18691696
45.TavaresL.FigueiraI.MacedoD.Mc DougallG. J.LeitaoM. C.VieiraH. L. A.StewartD.AlvesP. M.FerreiraR. B.SantosC. N.2012Neuroprotective effect of blackberry (Rubus sp.) polyphenols is potentiated after simulated gastrointestinal digestionFood Chem.13114431452
46.TavaresL.FigueiraI.Mc DougallG. J.VieiraH. L.StewartD.AlvesP. M.FerreriraR. B.SantosC. N.2012Neuroprotective effects of digested polyphenols from wild blackberry speciesEur. J. Nutr.Doi: 10.1007/s00394-012-0307-7
47.García-NebotM. J.CillaA.AlegríaA.BarberáR.2011Caseinophosphopeptides exert partial and site-specific cytoprotection against H202-induced oxidative stress in Caco-2 cellsFood Chem.12914951503
48.ElisiaI.TsopmoA.FrielJ. K.Diehl-JonesW.KittsD. D.2011Tryptophan from human milk induces oxidative stress and upregulates Nrf-2-mediated stress response in human intestinal cell linesJ. Nutr.14114171423
50.SamaranayakaA. G. P.KittsD. D.Li-ChanE. C. Y.2010Antioxidative and angiotensin-I-converting enzyme inhibitory potential of Pacific hake (Merluccius productus) fish protein hydrolysate subjected to simulated gastrointestinal digestion and Caco-2 cell permeationJ. Agric. Food Chem.5815351542
51.YaoL.FrielJ. K.SuhM.Diehl-JonesW. L.2010Antioxidant properties of breast milk in a novel in vitro digestion/enterocyte modelJ. Pediatr. Gastroenterol. Nutr.50670676
52.CoatesE. M.PopaG.GillC. I. R.Mc CannM. J.Mc DougallG. J.StewartD.RowlandI.2007Colon-available raspberry polyphenols exhibit anti-cancer effects on in vitro models of colon cancerJ. Carcinog.64
53.YoungD.NauF.PascoM.MineY.2011Identification of hen egg yolk-derived phosvition phosphopeptides and their effects on gene expression profiling against oxidative-stress induced Caco-2 cellsJ. Agric. Food Chem.5992079218
54.ChohanM.NaughtonD. P.JonesL.OparaE. I.2012An investigation of the relationship between the anti-inflammatory activity, polyphenolic content, and antioxidant activities of cooked and in vitro digested culinary herbsOxid. Med. Cell Longev.627843
55.Beyer-SehlmeyerG.GleiM.HartmannE.HughesR.PersinC.BöhmV.RowlandI.SchubertR.JahreisG.Pool-ZabelB. L.2003Butyrate is only one of several growth inhibitors produced during gut flora-mediated fermentation of dietary fibre sourcesBr. J. Nutr.9010571070
56.GleiM.HofmannT.KüsterK.HollmannJ.LindhauerM.Pool-ZabelB. L.2006Both wheat (Triticum aestivum) bran arabinoxylans and gut flora-mediated fermentation products protect human colon cells from genotoxic activities of 4-hydroxynonenal and hydrogen peroxideJ. Agric. Food Chem.5420882095
57.VeeriahS.HofmannT.GleiM.DietrichH.WillF.SchreierP.KnaupB.Pool-ZabelB. L.2007Apple polyphenols and products formed in the gut differently inhibit survival of human cell lines derived from colon adenoma (LT97) and carcinoma (HT29)J. Agric. Food Chem.5528922900
58.MunjalU.GleiM.Pool-ZabelB. L.ScharlauD.2009Fermentation products of inulin-type fructans reduce proliferation and induce apoptosis in human colon tumour cells of different stages of carcinogenesisBr. J. Nutr.102663671
59.BorowickiA.SteinK.ScharlauD.GleiM.2010Fermentation supernatants of wheat (Triticum aestivum L.) aleurone beneficially modulate cancer progression in human colon cellsJ. Agric. Food Chem.5820012008
60.BorowickiA.SteinK.ScharlauD.ScheuK.Brenner-WeissG.ObstU.HollmannJ.LindhauerM.WachterN.GleiM.2010Fermented wheat aleurone inhibits growth and induces apoptosis in human HT29 colon adenocarcinoma cellsBr. J. Nutr.103360369
61.LuxS.ScharlauD.SchlörmannW.BirringerM.GleiM.2011In vitro fermented nuts exhibit chemopreventive effects in HT29 colon cancer cells.Br J. Nutr.15110
62.SchlörmannW.HillerB.JanhsF.ZögerR.HennemeierI.WilheimA.LindhauerM. G.GleiM.2011Chemopreventive effects of in vitro digested and fermented bread in human colon cellsEur. J. Nutr10.1007/s00394-011-0262-8
63.FässlerC.GillC. I. R.ArrigoniE.RowlandI.AmadòR.2007Fermentation of resistant starches: influence of in vitro models on colon carcinogenesisNutr. Cancer588592
Written By
Antonio Cilla, Amparo Alegría, Reyes Barberá and María Jesús
Lagarda