Abstract
Aim of this research was to study the evolution of heat damage, phenolic acid content and in vitro antioxidant capacity of whole meal einkorn water biscuits baked at 205 °C for increasing times (10 min steps) from 25 to 75 min. The heat damage was gauged by determining furosine, hydroxymethylfurfural (HMF), furfural and glucosylisomaltol (GLI) contents. Furosine increased up to 50 min baking, when HMF started to form; furfural augmented only after 65 min treatment, whereas GLI did not change. An unknown compound, apparently related to the severity of the heat load, aroses through the aldolic condensation of HMF with the acetone used for the extraction of phenolic acids; hence the use of acetone-based solvents in thermally processed cereal products should be avoided. The conjugated phenolic acids ferulic, vanillic, syringic, p-coumaric, p-hydroxybenzoic and syringaldehyde and the bound phenolic acids ferulic, p-coumaric, syringic, and p-hydroxybenzoic were identified in water biscuits. The stronger heating treatments led to an increase of the soluble conjugated compounds, but did not influence the bound fraction. The in vitro antioxidant capacity of water biscuits augmented significantly as baking time increased, likely for the formation of antioxidant compounds as a consequence of heat damage.
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Introduction
Phenols are secondary metabolites synthesized by plants in response to pests, diseases and stresses. They are excellent oxygen radical scavengers, and as such can exert a beneficial impact on human health; in particular, they show anti-inflammatory, anti-microbial, anti-thrombotic, anti-atherogenic, vasodilatatory and cardio-protective effects [1]. Phenolic acids, the main phenols present in wheat kernels [2], are often scarce in commercial wheat flours, because they are mainly present in the aleuronic and hyaline layers, in the germ and in the seed coat [3, 4], which are usually eliminated during milling. Phenolic acids are present as soluble free, soluble conjugated and insoluble-bound [5]. The free soluble fraction represents about 1% of total phenols. The soluble conjugated phenolic acids, esterified to sugars and other low molecular weight components, and the insoluble-bound phenolic acids, linked to cell wall constituents, represent about 22% and 77% of the total phenols [2]. However, the free soluble phenols easily cross the human intestinal barrier, whereas bound and conjugated forms are not readily absorbable. A partial conversion from bound to conjugated during in vitro intestinal digestion has been observed [6]; additionally, bound phenolic acids can be partly degraded in the colon by bacterial enzymes [7, 8]. Although the bioavailability of phenolic compounds hydrolyzed by colon microbiota is lower than those of the free phenols readily absorbed in the small intestine [9], their abundance makes them a likely target to improve phenols nutritional availability. Therefore, several authors have studied the factors that trigger the passage from bound to conjugated phenolics during processing, such as maturation stage and fermentation [10], germination [11, 12], extrusion [13], baking [14], puffing [15], etc.
Some studies have investigated the changes in bioactive compounds and antioxidant capacity induced by baking, focusing mainly on heat damage and Maillard reaction products. Temperature, baking time and development of Maillard reactions can trigger the release of bound molecules as well as the loss of nutritional properties, along with an increase of Maillard reaction products and antioxidant capacity [16].
The reliable determination of phenolic acids is often a challenge, because the complex matrix and properties of foods hinder their retrieval. The free forms can be extracted using organic solvents, but the conjugated and bound forms require acid or base hydrolysis to free them from the cell wall matrix. Many solvents have been used to extract phenolic acids: ethanol–water [17], acidified methanol–water [18], isopropanol, acetonitrile, acetone–water [19], ethanol–acetic acid [20], methanol–acetone–water [21], etc.; in particular, this last mixture has been broadly adopted because of its effectiveness [4, 22, 23].
Einkorn (Triticum monococcum L. subsp. monococcum) is a diploid hulled wheat, allied to durum and bread wheat. The renewed interest for this cereal is linked to its high protein, carotenoid and tocol contents [15], as well as to its thrifty nature and disease resistance that favour low-input or organic management and propose it as an environment-friendly crop [24].
Aim of our research was to study the changes in phenolic composition and content, antioxidant capacity and heat damage of einkorn water biscuits (WB) during the baking process carried out for different times.
Materials and methods
Materials
Monlis, the most widespread Italian einkorn cultivar, was cropped in 2018–2019 at Sant’Angelo Lodigiano (45°13′40" N 9°25′21" E, Po plain, Italy) in 10 m2 plots arranged in a randomised complete block design with three replications, following standard cultural practices. After harvesting, the kernels from the three replications were combined and stored at 5 °C. Before processing, the seeds were de-hulled with an Otake FC4S thresher (Satake, Japan). Whole meal flour for biscuit preparation was obtained from kernels ground with a Cyclotec 1093 lab mill (FOSS Tecator, Denmark).
Water biscuits preparation
The WB were manufactured using only whole meal flour (30 g dry weight basis for each WB) and water, to unambiguously determine the role of flour in phenolic acid changes. Optimum water quantity and mixing time of each sample were determined by Brabender farinograph analysis. Dough mixing was carried out with a cookie dough micromixer (National Mfg. Co, Lincoln, Nebraska, USA). The dough was transferred to ungreased cookie sheets covered with parchment paper, rolled to 7 mm thickness using gauge strips and a rolling pin, and cut with a cookie cutter (inside diameter: 60 mm). Baking was carried out at 205 °C for increasing times (10 min steps) from 25 to 75 min, to study the changes under different heat conditions; acceptable water biscuits are obtained after 25 and 35 min, while after 55 min they become hard and after 75 min scorched. Four WB were prepared for each accession. Baked WB were collected, stored at − 20 °C until analysis, and finely ground with a commercial heavy-duty blender (Waring, Torrington, USA) just before analysis.
Chemical analysis
Dry matter (DM) content was determined following method 44–15 [25]. Water activity (aw) was evaluated using the Aqua Lab model Series 3 TE instrument (Decagon Devices, Inc, Pullman, WA, USA). Levels of furosine, glucosylisomaltol (GLI), hydroxymethylfurfural (HMF) and furfural in WB were determined by HPLC as reported by Hidalgo and Brandolini [26]. Soluble conjugated and insoluble-bound phenolic acids were analysed by RP-HPLC as described by Brandolini et al. [4]. The phenolic extracts were prepared as outlined in Moore et al. [23], with little modifications. Exactly 0.5 g of sample were mixed with 15 mL of a methanol/acetone/water (7:7:6) solution. After 15 min in an ice bath under discontinuous vortexing and after centrifugation (11,200 g, 10 min, 8 °C) with a Centrikon K24 centrifuge (Kontron Instruments, Bletchley, UK), the supernatant was recovered; the extraction from the sediment was repeated twice more, the three extracts were pooled and evaporated under vacuum at 35 °C for 18 min with a rotator evaporator Laborota 4000 (Heidolph, Milan, Italy). To recover the soluble conjugated and the insoluble-bound phenolic compounds, the pooled supernatants and the sediments were separately hydrolysed with 15 mL of 4 M NaOH under nitrogen for 4 h at room temperature and continuous shaking. The samples were then brought to pH 1.5–2.0 with 6 M HCL and extracted twice with 20 mL of ethyl ether/ethyl acetate (1:1 v/v). The extracts were clarified with anhydrous sodium sulphate, filtered with glass fibre 110 mm (Whatman, Maidstone, England), evaporated as previously outlined, suspended in 2 mL of methanol:water (1:1 v/v) and filtered with a 0.22 mm PTFE membrane (Millipore, Carrigtwohill Co, Cork, Ireland) for HPLC injection. All the analyses were performed twice.
Structural characterization of unknown chromatographic peak
The chromatographic peak eluting at 20.0 min during the RP-HPLC pattern of soluble conjugated phenolic acids was collected from ten runs and dried under vacuum at 20 °C. After dilution with water, the collected fraction was submitted to RP-HPLC/HR-MS using the same chromatographic conditions [4] and by coupling the HPLC separation module to a Q Exactive hybrid quadrupole-Orbitrap mass spectrometer through an HESI-II probe for electrospray ionisation (Thermo Scientific, San Jose, CA, USA). The ion source and interface conditions were: spray voltage + 3.0 kV, sheath gas flow 60 arbitrary units, auxiliary gas flow 20 arbitrary units and temperature 300 °C, capillary temperature 350 °C. Positive mass calibration was performed with Pierce LTQ ESI Positive Ion Calibration Solution (Thermo Scientific Pierce, Rockford, IL, USA). The RP-HPLC eluate was analyzed by Full MS and tandem MS analysis (MS2). The resolution was set at 70,000 and 17,500 and the AGC targets were 1 × 106 and 1 × 105 for Full MS and MS2 scan types, respectively. The maximum ion injection times were 50 ms. The MS data were processed using Xcalibur software (Thermo Scientific, San Jose, CA, USA).
The vacuum-dried fraction was also submitted to nuclear magnetic resonance (NMR) spectroscopy. To this purpose, the vacuum-dried fraction was dissolved in 0.6 mL methanol-d4 or acetone-d6 (Sigma-Aldrich, Milan, Italy) and immediately transferred to a 5 mm NMR tube (Wilmad 535-PP). 1H-NMR spectra were recorded at 25 °C on a Bruker AV600 spectrometer (Bruker Spectrospin AG, Rheinstetten, Germany), operating at 600.10 MHz for the 1H nucleus and equipped with a standard triple-resonance probe with z-axis gradients and temperature control unit. 1H-chemical shifts were measured in δ (ppm), using as reference the acetone-d5 residual peak, set at δ 2.096 [27]. All 2D spectra were obtained in phase-sensitive mode using standard pulse sequences. 2D-NOESY experiments were performed using 0.6 s mixing time, while the spin-lock duration for the 2D-TOCSY experiment was set at 80 ms. Other relevant acquisition parameters for all experiments: time domain: 4 K; number of scans: 16–48; relaxation delay for 2D-TOCSY: 2.5 s and for 2D-NOESY: 3 s. Raw data were Fourier-transformed after apodization with a 90°-shifted sine-bell-squared function, zero-filling to 2 K × 2 K real data points and baseline corrected. Spectra were processed using Bruker software TOPSPIN v.1.3. Spectral data are reported for the compound dissolved in acetone-d6.
Antioxidant capacity
The samples were extracted as in Yilmaz et al. [28]. Briefly, exactly 0.5 g sample were weighed and extracted with 5 mL of methanol:water (80:20 v:v) acidified with 1% HCl (MeOH:HCl) under agitation using Vortex (30 s) and a multi-rotator stirrer PTR-35 (Grant-bio, England) for 30 min at 4 °C in the dark. The mixtures were centrifuged at 11,200 g for 10 min at 8 °C and the supernatants recovered; after re-extracting the residues, the supernatants were pooled, giving 10 mL crude extracts.
The saturated butanol (BuOH) extracts were obtained performing a single extraction with 0.5 g of sample and 10 mL of solvent under agitation with Vortex (30 s) and orbital stirrer (2 h) at 4 °C in the dark followed by centrifugation as formerly described.
The ABTS [2,2′-azino-bis(3-ethylbenzothiazoline-6-sulphonic acid)] radical cation scavenging capacity was analysed as described by Re et al. [29], with the minor changes reported by Yilmaz et al. [28]. The FRAP (reduction of the Fe(III)e2,4,6-tripyridyl-s-triazine complex to the ferrous form at low pH) test was determined following Benzie and Strain [30], with the small modifications described by Yilmaz et al. [28]. The antioxidant capacity was expressed as mmol TE/kg DM.
Results and discussion
To better understand the relationships among content of soluble conjugated and insoluble-bound phenolic acids, antioxidant capacity and heat damage, their evolution was studied during baking of WB prepared from Monlis whole meal flour (Fig. 1a–d, respectively). Furosine increased up to 45 min and then steeply declined, HMF started growing after 45 min, in correspondence to furosine decrease, while GLI and furfural somewhat augmented only after long baking times. The evolution of these heat-damage markers was similar to that reported by Hidalgo and Brandolini [26] during baking of WB made from refined bread wheat flour; nonetheless, the levels of GLI, furosine, HMF and furfural were generally higher (Fig. 1d) in the einkorn WB studied in the present work. Ait Ameur et al. [31] studied the kinetics of HMF in the advanced stages of baking and observed that HMF was very sensitive to aw, reporting that a low aw (0.51) at baking temperatures of 200–250 °C was critical for HMF formation. The aw in the whole meal flour WB was 0.80 after 25 min and decreased to 0.48 at 35 min, while the aw in the white flour WB remained stable at 0.8 up to 55 min [26].
Two major unknown peaks appeared at 12 and 20 min retention times in the RP-HPLC pattern of the soluble conjugated extracts (Fig. 2a). The former compound increased until 45 min and then rapidly diminished, while the latter compound continued growing (Fig. 1a). Their evolution mirrored those of furosine and HMF, respectively (Fig. 1d). Therefore, the importance of the compound eluting at 12 min and its possible contribution to the antioxidant capacity are probably limited to foods from low heat-stress treatments. On the other hand, the compound eluting at 20 min may be a major player in determining the antioxidant properties of bakery products under severe heat-stress conditions. Its spectrum differed from that of HMF (maximum absorbance wavelength at 327 nm instead of 284 nm, respectively). To identify this compound, the eluting fraction corresponding to the unknown peak was collected from RP-HPLC and was analysed by RP-HPLC/HR-MS. Surprisingly, the resulting chromatographic pattern showed a peak eluting at 22.5 min in addition to the expected one eluting at 20.0 min (not shown). Both peaks had the same UV spectrum (maximum absorbance at 327 nm) and the same accurate mass (MH+: 167.0630), corresponding to a C9H10O3 molecular formula (calculated: 166.06298 Da). The MS1 spectra of the two chromatographic peaks overlapped completely and three major fragments (MH+: 149.0598, 121.0651, 93.0706) were recorded.
The 1H-NMR spectrum (600 MHz, acetone-d6; Fig. 3a) confirmed the presence of two molecules at an approximately 75:25 molar ratio. The 1H-NMR spectrum of the major component (75%) exhibited two trans-olefinic protons at δ 7.40 and 6.55 (3JH,H = 16.0 Hz), two aromatic signals at δ 6.84 and 6.48 (3JH,H = 3.4 Hz), one oxygenated methylene group as a singlet at δ 4.62, and one methyl singlet at δ 2.32. The 1H-NMR spectrum of the minor component (25%) exhibited two cis-olefinic protons at δ 6.67 and 6.22 (3JH,H = 13.4 Hz), two aromatic signals at δ 7.81 and 6.46 (3JH,H = 3.4 Hz), one oxygenated methylene group as a singlet at δ 4.59, and one methyl singlet at δ 2.29. The small value of the vicinal coupling constant between the aromatic protons suggested a furyl moiety. For both components, the 1H connectivity and spatial proximity were established by analysis of 2D-TOCSY/COSY and 2D-NOESY experiments, respectively. The hydroxymethylene group (CH2OH) showed a long-range connectivity with 6-H and 7-H of the furyl moiety (Fig. 3a), while the methyl group was detected by means of the NOESY interaction observed for the olefinic protons (Fig. 3b). Chemical shifts and coupling constants were consistent with published data for 4-[5-(hydroxymethyl)-2-furyl]-3(E)-buten-2-one [32]. Some minor discrepancies might be explained by the different solvents used for the NMR experiments (acetone-d6 vs. chloroform-d). Finally, the UV maximum absorbance, with a measured 43 nm bathochromic effect compared to HMF (λmax = 283 nm), confirmed the presence of an α,β-unsatured ketone-conjugated furane chromophore. Hence, on the basis of RP-HPLC/HR-MS and NMR data, the chromatographic peak eluting at 20.0 min should be assigned to 4-[5-(hydroxymethyl)-2-furanyl]-3(E)-buten-2-one (Fig. 3, compound 1). The additional peak at 22.5 min was the less thermodynamically stable isomer 4-[5-(hydroxymethyl)-2-furanyl]-3(Z)-buten-2-one (Fig. 3, compound 2), likely to result from the isomerisation of 3-buten-2-one,4-[5-(hydroxymethyl)-2-furanyl]-(3E) during vacuum drying. These two molecules originate from the aldol condensation and subsequent dehydration of HMF with acetone during the extraction of phenolic compounds. Such a reaction has been thoroughly studied in the production of fuels from biomass-derived carbohydrates [33] and there is a general agreement about the positive role of metal oxides as Lewis acids in the aldol condensation catalysis [34]. As whole meal flours are generally rich in divalent ions [35], given the basic conditions used during the extraction process (see “Materials and methods”), it is feasible to assume that the WB prepared from whole meal flour provide the right catalytic conditions to promote an aqueous-phase aldolic condensation of HMF with the acetone used as an extraction solvent (see scheme in Fig. 4) [36].
The two isomers represent, therefore, chemical artefacts, which must be considered when using acetone for assessing the phenolic acid composition of baked products. A clear-cut evidence that compounds 1 and 2 derive from HMF during the extraction is reported in Fig. 5, which compares the HPLC analysis of extracts performed with and without acetone (traces A and B, respectively). It is evident that compound 1 was detected only in the acetone extract, at a concentration inversely proportional to that of HMF.
The conjugated phenolic acids (Fig. 2a) identified in the WB were ferulic, vanillic, syringic, p-coumaric, p-hydroxybenzoic and syringaldehyde, while the bound phenolic acids (Fig. 2b) were ferulic (by far the most abundant), p-coumaric, syringic, and p-hydroxybenzoic acids. These phenols (plus caffeic acid at low concentration) were also observed in similar products [15]. In the soluble phenolic extracts, ferulic and p-coumaric acid initially increased, but then decreased significantly after 45 min, while p-hydroxybenzoic acid, syringic acid and syringaldehyde increased slightly and vanillic acid kept growing steadily throughout all the baking time; the insoluble-bound fraction composition, instead, generally did not change, although vanillic acid steadily increased during baking. These results are in line with those reported by Hidalgo et al. [15] for WB baked for 25 and 35 min. The same authors noticed that stronger heating treatments, such as those applied during kernels puffing, led to higher increases of the soluble conjugated compounds, but still did not influence the bound fraction. The authors suggested that the increase in soluble conjugated phenolic acids might be related to heat-induced rupture of certain ester bonds, and thus to an increase in extractable compounds.
The insoluble-bound phenolic acids syringic, caffeic, p-coumaric and ferulic did not show significant variations during baking, whereas the p-hydroxybenzoic and vanillic acids increased slightly from 45 min onwards. Hence, the increase of some phenolic acids in the soluble conjugated fraction does not seem to be related to a partial degradation of insoluble-bound phenolics.
The in vitro antioxidant capacity of saturated butanol and acidified methanol–water extracts augmented significantly as the baking time passed from 25 to 75 min (Fig. 1c). This increase does not seem justified by the changes in concentration of phenolic acids or of other antioxidant molecules such as carotenoids and tocols, whose levels diminish during processing [37, 38]. Therefore, the most likely explanation is the formation of antioxidant compounds during baking as a consequence of the Maillard reaction, as suggested for bread crust [39, 40] and for biscuits [41, 42].
Conclusions
This research demonstrates the high stability of soluble conjugated and insoluble-bound phenolic acids even after long baking times. The increased antioxidant capacity after baking is more a consequence of heat damage than of conjugated and bound phenols liberation. The use of acetone during extraction should be considered with caution or even avoided, as it might lead to artefacts arising from undesired aldol condensation products with furan aldehydes. Nevertheless, the effectiveness of other solvents for extracting free phenols from water biscuits and, in general, thermally processed cereal products needs further experimental evidence.
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Santa Cruz Olivos, J.E., De Noni, I., Hidalgo, A. et al. Phenolic acid content and in vitro antioxidant capacity of einkorn water biscuits as affected by baking time. Eur Food Res Technol 247, 677–686 (2021). https://doi.org/10.1007/s00217-020-03655-0
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DOI: https://doi.org/10.1007/s00217-020-03655-0