Impact of Gastrointestinal <i>In Vitro</i> Digestion and Deficit Irrigation on Antioxidant Activity and Phenolic Content Bioaccessibility of “Manzanilla” Table Olives

Sánchez-Rodríguez, Lucía; Cano-Lamadrid, Marina; Carbonell-Barrachina, Ángel A.; Hernández, Francisca; Sendra, Esther

doi:https://doi.org/10.1155/2020/6348194

Journal of Food Quality

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Abstract Introduction Materials and Methods Results and Discussion Conclusions Data Availability Conflicts of Interest Acknowledgments References Copyright Related Articles

Research Article | Open Access

Volume 2020 | Article ID 6348194 | https://doi.org/10.1155/2020/6348194

Impact of Gastrointestinal In Vitro Digestion and Deficit Irrigation on Antioxidant Activity and Phenolic Content Bioaccessibility of “Manzanilla” Table Olives

Lucía Sánchez-Rodríguez,¹Marina Cano-Lamadrid,²Ángel A. Carbonell-Barrachina,¹Francisca Hernández,²and Esther Sendra³

Academic Editor: Flora V. Romeo

Received18 Dec 2019

Revised18 Feb 2020

Accepted02 Mar 2020

Published01 Apr 2020

Abstract

This was the first study investigating the polyphenol content, antioxidant potential, and polyphenol bioaccessibility after in vitro digestion of table olives grown using regulated deficit irrigation (RDI) treatments to save irrigation water. Two experiments were carried out: (i) experiment A, where RDI was applied during the pit hardening stage and (ii) experiment B, where RDI was applied during the rehydration stage. Only slight differences among irrigation treatments were observed in two antioxidant assays (ABTS^+• and DPPH^•) and on TPC for the soluble fraction after in vitro digestion. An average of 1 g gallic acid equivalents kg⁻¹ of table olives were found after digestion. Approximately, 12% of the polyphenols of table olives were bioaccessible for human absorption. Saving water techniques influence neither the final polyphenol content and antioxidant potential of table olives nor the bioaccessibility of polyphenols. The consumption of 40 g of table olives will provide 40 mg of bioaccessible polyphenols able to provide associated health benefits (∼7% of the daily polyphenols intake recommendation).

1. Introduction

Table olives are a common constituent of Mediterranean diet and have beneficial effects on human health because they are antioxidant-rich foods [1]. Olives are rich in polyphenols (1-2% of its composition), and these compounds provide antioxidant, anti-inflamatory, and antitumoral properties to table olives. Olive composition can be affected by several factors such as climate, agronomic conditions, and the processing method. [2]. Nowadays, regulated deficit irrigation (RDI) strategies are being implemented on olive tree orchards with the main purpose of saving water. Additionally, moderate RDI strategies are being investigated in table olives due to their “potential” effect on enhancing the accumulation of bioactive compounds and improvement of the intensity of key sensory attributes; these special table olives are known as hydroSOStainable [3].

Studying the bioaccessibility of antioxidant and polyphenolic compounds is crucial to know their real behavior and activity in vivo. Bioaccessibility is defined as the tendency of compounds to be extracted from the food matrix and then, be available for intestinal cell absorption [1]. For that purpose, gastrointestinal in vitro digestion simulation is a model to extract compounds from the test matrix simulating human digestion, and although it is important to consider that several factors (gender, age, intestinal conditions, etc.) will affect digestion, this model is still a good alternative to avoid animal testing methods and promote animal protection [4].

In the present research, “Manzanilla” Spanish-style table olives grown under different RDI strategies (experiment A: water irrigation was reduced during the pit hardening stage; experiment B: water irrigation was reduced during the rehydration stage) were subjected to a gastrointestinal in vitro digestion simulation with the purpose to study how the lack of water during cultivation affects the polyphenol content, polyphenol bioaccessibility, and antioxidant activity by three methods after simulation of human digestion.

2. Materials and Methods

2.1. Experimental Conditions and Irrigation Treatments

Two irrigation experiments were carried out in this study on cultivar “Manzanilla” to evaluate the effect of water stress at two phenological stages:

2.1.1. Experiment A

(i)A0 (optimum water status): trees were fully irrigated(ii)A1 (moderate deficit irrigation): the threshold value for water stress level (ψ_stem) was −2 MPa during the pit hardening stage (day of the year (DOY) 169 to DOY 240)(iii)A2 (severe deficit irrigation (short time)): the threshold value for ψ_stem was −3 MPa during half period of the pit hardening stage (from DOY 169 to DOY 206)(iv)A3 (severe deficit irrigation (long time)): the threshold value for ψ_stem was −3 MPa until end of period of the pit hardening stage (DOY 169 to DOY 240)

2.1.2. Experiment B

(i)B0 (optimum water status): trees were fully irrigated(ii)B1 (moderate deficit irrigation before harvest (short time)): the threshold value for ψ_stem was −2 MPa at the beginning of September without the rehydration period (2 weeks before harvest)(iii)B2 (moderate deficit irrigation (long time)): the threshold value for ψ_stem was −2 MPa from mid-August without the rehydration period (four weeks before harvest)

Experiment A was carried out in a farm located in Dos Hermanas (Seville, Spain, 37°25′N, 5°95′W). “Manzanilla” olive trees were ∼30 years old and were spacing following a 7 × 4 square pattern. Irrigation was performed at night by drip with one lateral pipe per row of trees and four emitters (each delivering 2 L h⁻¹) per plant.

With respect to experiment B, the farm was located in Coria del Río (Seville, Spain, 37°17′N, 6°3′W). “Manzanilla” olive trees were ∼44 years old and were spacing following a 7 × 5 m square pattern. Also, irrigation was carried out during night by one lateral pipe per tree row and five emitters (each delivering 8 L h⁻¹) per plant. Specific agronomy characteristics could be found in [5]. Different locations were used because of land availability, although, as explained before, similar conditions characterized the field and weather.

Field characteristics of both experiments could be found in the work by Sánchez-Rodríguez and Cano-Lamadrid et al. [3]. Climatic conditions could be considered equal for both experiments because only 10 km separated the farms. A total rainfall amount of 258.94 mm was registered on experiment A from 3 September 2015 to 20 September 2016, while 254,25 mm of total rainfall amount on experiment B from 8 September 2015 to 27 September 2016. Winter minimum temperatures were around 0°C, and spring temperatures determine flowering around mid-April. Pest control, pruning, and fertilization practices were those commonly used by growers.

Stress integral (Ψ_int) was calculated to study the accumulative stress of olive trees produced du to reduction of water irrigation [6].where Ψ_int is the stress integral, Ψ is the average midday stem water potential for any interval, and n is the number of days of the interval.

Olives were collected by hand at their mature-green stage on September 2016.

2.2. “Spanish-Style” Processing

Raw olives were processed following “Spanish-Style” to table olives as previous described in [7]. Briefly, raw olives were treated with NaOH solution (1.3–2.6% weight:volume) for 6–8 h with the purpose to remove oleuropein, and then, olives were washed with water for 12–14 h to remove residual NaOH. Olives were put on 10–12% NaCl solution for fermentation until table olives-brine equilibrium was reached (pH < 4.2, 8–9% (weight:volume) NaCl, 0.7–1.0% lactic acid and residual alkalinity < 0.120 N).

2.3. Gastrointestinal In Vitro Digestion Simulation

In vitro digestion simulation was carried out following the method described in [8] on table olives of all irrigation treatments under study. Firstly, salivary solution simulation (SSS), gastric solution simulation (GSS), and intestinal solution simulation (ISS) were carried out using KCl (0.5 M), KH₂PO₄ (0.5 M), NaHCO₃ (1 M), NaCl (2 M), MgCl₂ (H₂O)₆ (0.15 M), and (NH₄)₂CO₃ (0.5 M) following indications in [8]. Simulation of the oral phase was carried out with 10 g of table olives and simulating mastication with α-amylase (1500 U mL⁻¹) (Enzyme Commission (EC) number 3.2.1.1) and SSS. The mixture was placed in a stomacher bag and stomached for 10 minutes to simulate the mastication (Stomacher Laboratory Blender, Bioxia, Thane, India). The resulting mixture was transferred to a glass bottle. Then, the gastric phase was carried out with pepsin (2500 U mL⁻¹) (EC number 3.4.23.1) for 1 h at 37°C, 170 rpm (Thermostatic bath with agitation BSH, Raypa, Barcelona, España), and pH 3 (adjusted with HCl, 6 M) and GSS. Finally, the intestinal step was performed with ISS, pancreatin (800 U mL⁻¹) (EC Number 232.468.9), and bile salts (160 mM) at 37°C, 170 rpm, and pH 7 (adjusted with NaOH, 1 M) for 2 hours. After the intestinal phase, liquid soluble fraction (SF) and solid residual fraction (RF) were collected. The SF was centrifuged at 10,000 rpm for 10 min at 4°C (Sigma 3–18 K; Sigma Laborzentrifugen, Germany) for later analysis.

2.4. Antioxidant Activity and Total Phenolic Content

Nondigested table olives (test matrix (TM)) and RF were extracted as described by previous authors [9]. Briefly, 2 g of fresh sample was mixed with 10 mL of MeOH/water (80 : 20 v/v) + 1% HCl. This mixture was sonicated for 15 min, and then, it was left overnight at 4°C. The next day, samples were sonicated again for 15 min and centrifuged at 10,000 rpm for 10 min at 4°C (Sigma 3–18 K; Sigma Laborzentrifugen, Germany).

Antioxidant activity of TM, SF, and RF was measured using three assays: (i) ABTS^+• as reported in [10], (ii) DPPH^• as reported in [11], and (iii) FRAP following protocol in [12]. Additionally, TPC assay was carried out as in [13]. All analyses were performed using an UV-visible spectrophotometer (Helios Gamma model, UVG 1002E). Results for antioxidant activity were quantified using calibration curves with Trolox and expressed as mmol Trolox kg⁻¹ of table olives. TPC calibration curves were obtained with gallic acid, and results were expressed as gallic acid equivalents (GAE), g kg⁻¹ of table olives.

TPC bioaccessibility, expressed as the percentage of total polyphenols liberated from the TM after the gastrointestinal digestion, was calculated as previously reported by [14]:where CF is the polyphenols concentration in the SF fraction and CI is the initial polyphenols concentration in undigested flesh table olives.

2.5. Statistical Analysis

One-way analysis of variance (ANOVA) was carried out to study the effect of RDI treatment, and then, Tukey’s multiple range test was used to compare the means. The standard deviation (SD) of the mean is used to perform Tukey’s test; therefore, the SD values were not included in tables to avoid repetition of the data and to make tables easier to understand. Statistical differences were considered significant at three levels: (i) (), (ii) (), and (iii) (). An XLSTAT (2016.02.27444 version, Addinsoft) was used to perform all statistical analysis.

3. Results and Discussion

3.1. Irrigation

As can be seen in Table 1, different levels of water stress were reached by olive trees. In experiment A, it could be found that A0 presented the lowest Ψ_int because it was not submitted to stress (control treatment). The A1 (moderate deficit irrigation) and A2 (severe deficit irrigation during short time) trees had intermediate and equivalent Ψ_int values, while A3 (severe deficit irrigation during long time) trees presented the highest Ψ_int value. In experiment B, although B0 (control) was fully irrigated, it could be seen that its Ψ_int value was higher than that of B1 (moderate deficit irrigation during short time before harvest). This experimental fact can be justified because even though researchers can control the applied water volume, other natural factors such as overall weather (e.g., rain) or soil differences among areas of the same field can also significantly affect Ψ_int. Finally, B2 presented the highest Ψ_int value due to water stress was moderate but during a long time before harvest.

3.2. Antioxidant Activity and Total Phenolic Content

Results of antioxidant activity and TPC of table olives under study are shown in Table 2. In experiment A, no statistical differences were found among irrigation treatments in the antioxidant activity of the TM. Regarding ABTS^+• assay, in the SF and total (SF + RF) fractions, it was found that the higher the stress, the higher the antioxidant potential. With respect to the percentage of variation (% var), after gastrointestinal in vitro digestion, for ABTS^+•, it was found a decrease of ∼76% and the smallest decrease was found for A3 table olives (those with the highest water stress). Regarding DPPH^•, in the SF and total fractions, the highest value was found on A1 at a moderate stress level, while olives from the A3 treatment (highest water stress) showed a decrease on DPPH^• in comparison to control (A0). The DPPH^• % var was higher than that of ABTS^+•, with a ∼95% decrease. FRAP assay did not show statistical differences in any fraction under study, and the % var was ∼92%. Concerning TPC, only SF showed statistical differences between irrigation treatments, and a small increase (2.8%) was found between control and three RDI table olives. A decrease of ∼82% was found with respect to the variation percentage.

Regarding experiment B, TM showed statistical differences on DPPH^• and FRAP assays, as well as on TPC. For DPPH^• and TPC, both RDI treatments showed higher values than control, being the highest B1, while in FRAP assay, B1 was the treatment that presented the lowest value. No statistical differences between treatments were found after gastrointestinal in vitro digestion simulation for this experiment. For ABTS^+•, it was found an average of 1.4 mmol Trolox kg⁻¹ of total fraction and a % var of ∼−85%. For DPPH^• values showed an average of 0.4 mmol Trolox kg⁻¹ for total fraction with a % var of ∼−95%. With respect to FRAP assay, total fraction showed an average of 1.31 mmol Trolox kg⁻¹ and a % var of ∼−93%. Finally, average TPC was 0.99 g GAE kg⁻¹ and TPC had a % var of ∼−83%.

Although no statistical differences between irrigation treatments were found on RF, some assays showed higher values than control, such as DPPH^• (∼0.4 mmol Trolox kg⁻¹) and TPC (∼0.3 g GAE kg⁻¹). Those values could be relevant because they might indicate that there are still antioxidant and polyphenolic compounds that could be metabolized by the colon microflora, and thus, it points to a potential increase in bioavailability. Therefore, RF values found on table olives coming from deficit irrigation strategies indicated that stress caused on plant could affect the final bioavailability of antioxidants and polyphenols increasing the content of these compounds available for human absorption [15].

Figure 1 represents the percentage of bioaccessibility of TPC after the gastrointestinal in vitro digestion simulation. In both experiments, no statistically significant differences were found among irrigation treatments. In experiment A, A0 presented 11.5%, A1, 11.1%, A2, 12.1%, and A3, 13.1% of TPC bioaccessibility. In experiment B, control (B0) was 13.2% bioaccessible, while B1 and B2 treatments showed 12.2 and 12.3% of TPC bioaccessibility, respectively.

(a)

(b)

The decrease on antioxidant capacity and phenolic compounds content may be related to their degradation. A high proportion of table olive polyphenols are very susceptible to chemical degradation when they are submitted to the acidic conditions of digestion [15]. It was formerly described the polyphenolic profile of hydroSOStainable table olives of the current research [3], and it was found an increase of oleuropein, comselogoside, and verbascoside on A1 treatment as compared with control, as well as an increase of elenoic acid glucoside, oleuropein, and comselogoside regarding RDI treatments of experiment B. Beside this increases, it was previously reported that only 25% of oleuropein (one of the most important polyphenols in table olives) was stable during digestion, as well as only 20% of comselogoside and elenoic acid derivatives [15]. Flavonoids, verbascoside, and hydroxytyrosol derivatives also presented a small TPC bioaccessibility in a research conducted with three table olives cultivars [14]. Flavonoids are not very soluble in either organic or aqueous solvents and are usually present in foods in combination with sugars in the form of glycosides [16], so it is possible that higher concentrations that were found on RDI table olives on some flavonoids such as luteolin [3] would probably not have been extracted from the olive pulp during the in vitro digestion simulation.

Similar results, to the ones reported in the current study, have been previously reported in “Cornezuelo” table olives [15]. For instance, it was found a high decrease of DPPH^• and ABTS^+• after gastrointestinal digestion simulation and also a decrease of 75% of TPC.

Several factors can influence the phenolic bioaccessibility. The digestion process could produce changes on polyphenol composition modifying their original profile. The food matrix where polyphenols are found could also influence the extraction [16]. It has been previously reported that the fermentation process suffered during table olives preparation and the olive cultivar could influence the final polyphenol extraction [14].

There is lack of information about the how the stress suffered by plants is related to the later metabolism of the compounds by human digestive apparatus. In the present research, the water stress suffered by olive trees due to irrigation strategies did not provide significant differences among treatments on final TPC and bioaccessibility in both experiments. It has been demonstrated that it is possible to save irrigation water without having significant effect on the final polyphenolic compounds available for human absorption. Daily intake of polyphenolic compounds is very important because of their associated health benefits. Higher total consumption of 600 mg per day would provide a protective effect against chronic diseases [17]. Consequently, eating 10 hydroSOStainable table olives per day (40 mg of bioaccessible polyphenols) would contribute to a ∼7% of this total polyphenol intake recommendation.

4. Conclusions

This is the first study investigating the effect of gastrointestinal in vitro digestion simulation on antioxidant potential and total polyphenol content, and its bioaccessibility of table olives submitted to regulated deficit irrigation strategies. Water stress was applied during two growing stages, experiment A: the pit hardening stage and experiment B: during the rehydration phase. Results showed that, in experiment B, antioxidants and polyphenols were not affected by the stress after gastrointestinal in vitro digestion simulation, while in experiment A, regarding TPC, ABTS^+•, and DPPH^•, slight differences were found among treatments. In general, a total of ∼1 g GAE kg⁻¹ was extracted after digestion, indicating that the bioaccessibility of the TPC of both control and hydroSOStainable table olives was ∼12%. Therefore, the daily intake of 10 hydroSOStainable table olives entails the intake of 40 mg of “bioaccessible” polyphenols and involve the daily of ∼7% of polyphenols intake recommendation for protective effect against chronic diseases.

Data Availability

The data used to support the findings of this study are included within the article.

Conflicts of Interest

The authors declare that they have no conflicts of interest.

Acknowledgments

This study has been funded by (Ministerio de Ciencia, Innovación (MCI) Agencia Estatal de Investigación (AEI) and Fondo Europeo de Desarrollo Regional (FEDER)) through a coordinated research project (hydroSOS mark) including the Universidad Miguel Hernández de Elche (AGL2016-75794-C4-1-R, hydroSOS foods) and the Universidad de Sevilla (AGL2016-75794-C4-4-R) (MCI/AEI/FEDER, UE). Author Marina Cano-Lamadrid was funded by a FPU grant from the Spanish Ministry of Education (FPU15/02158).

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Copyright

Copyright © 2020 Lucía Sánchez-Rodríguez et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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