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Chemistry and Biology of Aroma and Taste
Quantitative analyses of key odorants and their precursors reveal differences In the aroma of gluten-free rice bread compared to wheat bread Anke R. Boeswetter, Katharina Anne Scherf, Peter Schieberle, and Peter Koehler J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.9b04800 • Publication Date (Web): 05 Sep 2019 Downloaded from pubs.acs.org on September 5, 2019
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Journal of Agricultural and Food Chemistry
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QUANTITATIVE ANALYSES OF KEY ODORANTS AND THEIR PRECURSORS
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REVEAL DIFFERENCES IN THE AROMA OF GLUTEN-FREE RICE BREAD
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COMPARED TO WHEAT BREAD
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Anke R. Boeswetter1, Katharina A. Scherf1, Peter Schieberle2, Peter Koehler3*
5 6
1
7
Meitner-Str. 34, 85354 Freising, Germany
8
2
9
Garching, Germany
10
Leibniz-Institute for Food Systems Biology at the Technical University of Munich, Lise-
Department of Chemistry, Technical University of Munich, Lichtenbergstrasse 4, 85748
3 Biotask
AG, Schelztorstraße 54‑56, 73728 Esslingen, Germany
11 12 13 14 15 16 17 18 19
* To whom correspondence should be addressed
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Phone: +49 711 31059068
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Fax: +49 711 31059070
22
E-mail:
[email protected] -1-
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ABSTRACT
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Rice flour is one of the most important raw materials in gluten-free products. However, the
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aroma of gluten-free rice bread is less accepted by consumers than that of commercial
26
wheat bread. Therefore, 18 selected aroma compounds were determined in rice and
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wheat breads by stable isotope dilution assays (SIDA) to elucidate differences in the
28
sensory characteristics, concentrations and odor activity values (OAV). The OAVs of most
29
aroma compounds varied greatly between a rice and a wheat bread. In particular, 2-
30
aminoacetophenone with a grape-like, medicinal aroma was characteristic for rice bread
31
crumb and crust, while maltol was only relevant in wheat bread crust. Ehrlich pathway
32
products varied in their concentration between the bread crumbs and were correlated with
33
the contents of their corresponding free amino acid precursors in the flours and doughs.
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The analysis of rice flour revealed that only few aroma compounds retained in the bread.
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Consequently, the bread making process has a high relevance in aroma compound
36
formation. By comparison of breads prepared from fresh and stored rice flour, hexanal
37
was identified as an important indicator for ageing in rice bread and flour.
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KEYWORDS
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Stable isotope dilution analysis (SIDA); Odor activity values (OAV); Gluten-free; Rice
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bread; Wheat bread; Free amino acids; Flour aging
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INTRODUCTION
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Due to its worldwide availability, low allergenicity and cheap price rice flour is one of the
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most important raw materials for the production of gluten-free bread.1–5 Moreover the
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production of gluten-free products has grown strongly in recent years.6 Not only patients
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suffering from gluten- and wheat-dependent hypersensitivities, such as celiac disease,
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wheat allergy or non-celiac gluten sensitivity (NCGS), but also healthy people consume
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gluten-free products.7 However, one of the most important issues of gluten-free bread
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making is the poor quality of the products in terms of aroma and texture compared to
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wheat bread.8,9 A prerequisite for the improvement of the aroma of rice bread is (i) the
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systematic characterization of its aroma compounds and (ii) the comparison with those of
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wheat bread. The application of an aroma extract dilution analysis (AEDA) recently
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resulted in the identification of the key aroma compounds in a rice bread and a comparison
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to wheat bread aroma compounds.10. 2-Aminoacetophenone (medicinal, grape like) and
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4-vinylphenol (phenolic) were highly relevant in the crumb and crust of rice bread, whereas
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1-octene-3-one (mushroom-like) and (E)-2-nonenal (green, fatty) were important uniquely
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in the crust of rice bread. Compared to wheat bread, in rice bread maltol (caramel-like)
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and 2-methoxy-4-vinylphenol (smoky, clove-like) were absent. Yeast metabolites formed
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via the Ehrlich pathway such as 3-methyl-1-butanol (malty), 2- and 3-methylbutanoic acid
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(sweaty), 2-phenylethanol (flowery, honey-like) and phenylacetic acid (honey, bees-wax),
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reached relevant FD factors in both bread types. Correlations between the presence of
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aroma compounds and the texture of the breads were not established. Because AEDA
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does not consider matrix effects and volatility it is necessary to quantitate aroma
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compounds by stable isotope dilution analysis (SIDA) and calculate odor activity values
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(OAV).11,12 However, comparative data on the concentrations and OAVs of relevant aroma
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compounds in rice and wheat bread were not available at the beginning of the study.
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Apart from quantitative data on aroma compounds, it is also important to study their
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formation pathways. Specific odorants are already present in the flour, and their content
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is affected by flour age, e.g. by lipid oxidation during long time storage.13 Other aroma
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compounds are formed from odorless precursors during the bread making process, such
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as free amino acids in the flour, which are important for the production of aroma active
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yeast metabolites.14 Knowledge on sources and precursors of aroma compounds is a
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prerequisite to modify or regulate aroma compound formation in gluten-free bread.
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Therefore, the aim of this study was to compare the amounts and OAVs of 18 selected
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aroma compounds in rice and wheat bread crumb and crust, respectively, and to elucidate
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the formation of aroma compounds. For this purpose, the concentrations of the free amino
78
acids leucine, isoleucine and phenylalanine were monitored and compared to the contents
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of the corresponding aroma-active metabolites. Additionally, concentrations and OAVs of
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12 aroma compounds in rice flour were determined to estimate the impact of the flour on
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the aroma of the bread. To verify the previously reported effect of flour age on rice bread
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aroma, fresh and stored rice flour batches and the corresponding gluten-free breads were
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analyzed.
84 85
MATERIALS AND METHODS
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Raw materials and bread making. Two rice flour batches (batch R1: produced in
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10/2017, 88.6 % flour dry matter (fdm); batch R2: produced in 10/2015, 89.5 % fdm;
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Remyflo R7 90T LP; Beneo-Remy, Leuven-Wijgmaal, Belgium), wheat flour (W: 86.4 %
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fdm; ash content 0.55 %; “Rosenmehl”, Rosenmuehle GmbH, Ergolding, Germany), fresh -4-
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compressed baker’s yeast (F. X. Wieninger GmbH, Passau, Germany), sucrose (Alfa
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Aesar, Karlsruhe, Germany) and sodium chloride (Merck, Darmstadt, Germany) were
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used for bread making as previously described.10 After baking, breads were allowed to
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cool at room temperature (RT ~22 °C) for 2 h prior to analysis.
94 95
Chemicals. All chemicals, solvents, reference aroma compounds and amino acids were
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obtained from Merck (Darmstadt, Germany), Sigma Aldrich (Taufkirchen, Germany), Alfa
97
Aesar or Carl Roth GmbH (Karlsruhe, Germany) and were of analytical grade or higher.
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Dichloromethane (technical grade; VWR, Darmstadt, Germany) was purified by distillation
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before use. The isotopically labeled standards [d12]-hexanal, [d9]-3-methylbutanoic acid
100
and [d4,5]-2-phenylethanol were obtained from CDN isotopes (Quebec, Canada), [13C2]-
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phenylacetic acid and [13C6]-vanillin from Sigma Aldrich, [13C6]-leucine and [13C6]-
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isoleucine from Cambridge Isotope Laboratories (Andover, MA, USA) and [d5]-
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phenylalanine from Euriso-top (Saarbrücken, Germany). The following labeled
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compounds were synthesized as described before: [d2]-3-methyl-1-butanol,15 [d2,3]-1-
105
octene-3-one,16 [d2]-(E)-2-nonenal,17 [d4,5]-(E,E)-2,4-decadienal,18 [13C2]-maltol,19 [13C2]--
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nonalactone,20 [13C6]-2-methoxy-4-vinylphenol,21 [d3]-2-aminoacetophenone22 and [d4]-4-
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vinylphenol.22
108 109
Synthesis of [d20]-2-butyl-2-octenal. [d12]-Hexanal (1 mmol; 112 mg) was dissolved in
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a mixture of ethanol and aqueous sodium hydroxide (1 mol/L)(1.4 mL;1/1, v/v) .The
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solution was stirred overnight at 70 °C, extracted with dichloromethane (30 mL), and the
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organic phase was dried over sodium sulfate. The purity was verified using two-
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dimensional gas chromatography time-of-flight mass spectrometry (GC×GC-TOF-MS), -5-
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and the concentration was determined by gas chromatography coupled with a flame
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ionization detector (FID) compared to the unlabeled substance as described below.
116 117
Quantitation of the synthesized isotopically labeled internal standards: To
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determine the concentrations of isotopically labeled internal standards, peak intensities of
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GC-FID-chromatograms were compared with those of unlabeled reference aroma
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compound solutions using methyl octanoate as internal standard. Measurements were
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performed on a Thermoquest (Egelsbach, Germany) Trace 2000 GC equipped with a PAL
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autosampler (CTC-Analytics, Zwingen, Switzerland) and an FID. The response factor was
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used for the quantitation of the labeled isotopologues present in solution.
124 125
Quantitation of aroma compounds.
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Sample work up. Freshly baked bread samples were cooled for 2 h at RT and crumb and
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crust were separated. For homogenization, crumb and crust were frozen with liquid
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nitrogen and ground by a knife mill (GRINDOMIX GM 200; Retsch, Haan, Germany). Rice
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flour was used directly. Samples (1-100 g, depending on the analyte concentration
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determined in a preliminary analysis) were weighed into glass vessels. Dichloromethane
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(25-400 mL), the isotopically labeled standards were added, and samples were stirred at
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RT for 2 h. The volatile fraction was isolated by solvent-assisted flavor evaporation
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(SAFE)23, dried over anhydrous sodium sulfate and concentrated to 200-1000 µL at 53 °C
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by means of a Vigreux column (50 cm × 1 cm i.d.) followed by a micro distillation
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apparatus. All analyses were performed in triplicate.
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Quantitation by GC-MS. Samples containing known amounts of isotopically labeled
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standard were analyzed using different GC-MS systems depending on the MS
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fragmentation pattern and chromatographic separation needs (Table 1). The aroma
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compound concentrations were calculated by the ratio of the mass signals of analyte and
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standard and corrected with response calibration lines. These were determined by
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analyzing mixtures of the labeled and the unlabeled compounds in 5 different mass ratios
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(5:1 to 1:5) (Table 1). The lines were created by plotting the concentration ratios
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(standard/analyte) on the x-axis against the area ratios (standard/analyte) on the y-axis.
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Differentiation of geometric isomers. Mixtures of 2- and 3-methyl-1-butanol and 2-and 3-
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methylbutanoic acid, respectively, were prepared in 5 different ratios (5:1 - 1:5) and
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analyzed using an EI-GC-MS system. Calibration lines were created by plotting the
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intensity ratios of characteristic mass signals on the x-axis against the percentage of the
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respective 3-isomer in the mixture on the y-axis as follows: for the alcohols m/z 57 divided
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by m/z 70 and for the acids m/z 60 divided by the sum of m/z 60 and m/z 74.
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Quantitation of acetic acid. Acetic acid was quantitated by an enzymatic test kit (R-
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Biopharm, Darmstadt, Germany) according to the manufacturer’s instruction. Bread
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samples were homogenized as described above; flour was used directly. For the
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extraction, the sample (4 g) and water (ca. 60 mL) were heated for 20 min at 50-60 °C in
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a 100 mL flask. After cooling, the flask was filled up to the mark with water and the solution
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was filtered.
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Quantitation of free amino acids. -7-
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Sampling. Flour-water suspensions and bread doughs made from wheat and rice flour
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(R1), respectively, were prepared as previously described.10 Portions of 200 g suspension
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or dough were taken directly after mixing and after 10, 20, 30 and 40 min fermentation
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time (30 °C, 90 % relative humidity), respectively, frozen with liquid nitrogen, freeze dried
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and ground by a knife mill. Fresh compressed yeast (100 g) was ground by a cryomill
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(SPEX SamplePrep, Stanmore, United Kingdom) before freeze drying. Flour (100 g each)
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was lyophilized directly.
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Sample workup. Between 0.1 and 1 g sample (depending on the expected contents of
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amino acids) were weighed into centrifuge tubes containing 3.5 mL trichloroacetic acid
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(aq, 8.5 %) and the isotopically labeled internal standards (Table 2). After homogenization
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with a mechanical blender (Ultra Turrax, IKA, Staufen, Germany) and an extraction time
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of 3 min in an ultrasonic bath (Bandelin Electronic GmbH &Co. KG, Berlin, Germany), the
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samples were centrifuged for 20 min with 4500 × g at 15 °C in a Heraeus Multifuge X3 FR
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centrifuge (Thermo Fisher Scientific, Dreieich, Germany). The supernatant was poured
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onto Amicon® centrifugal filters (15 kDa, Merck) and centrifuged up to 12 h at 3000 × g.
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For derivatization, 2 mL of the filtrate was mixed with 2 mL aqueous sodium carbonate
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(1 mol/l, pH 9.8) and 0.5 mL benzoyl chloride (1 mol/l) solved in acetonitrile and stirred for
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30 min at RT. To stop the reaction, the pH was lowered to 2 using hydrochloric acid (32%,
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w/w). The samples were used either directly or diluted with aqueous acetonitrile (10%,
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v/v) for LC-MS/MS measurements. Amino acid concentrations were calculated from the
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ratio of the mass signal of analyte and labeled internal standard and corrected with
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response calibration lines (Table 2) as described for the quantitation of aroma compounds.
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Gas Chromatography-Mass spectrometry (GC-MS) Systems:
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High resolution (HR) GC-MS. An Agilent 7890B gas chromatograph (Waldbronn,
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Germany) was equipped with a PAL Autosampler (CTC-Analytics) and an ion trap detector
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type Saturn 2000 (Agilent). The samples were injected cold-on-column. Chromatography
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was performed on an Agilent DB-FFAP capillary (30 m × 0.25 mm i.d.; 0.25 μm film
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thickness) using helium as carrier gas and the following temperature program: 40 °C held
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for 2 min, 6 °C/min up to 230 °C, held for 5 min. The characteristic ions were monitored in
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the chemical ionization mode (MS-CI) with methanol as reactant gas.
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Two-dimensional “heartcut”-GCxGC-MS. The system consisted of a Thermo Fisher
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Scientific Trace 2000 series GC equipped with a PAL Autosampler (CTC-Analytics), an
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FID, a sniffing port and a Thermo Fisher Scientific moving column stream switching
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system (MCSS) connected to a Varian CP 3800 gas chromatograph (Waldbronn,
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Germany) coupled to an Agilent Saturn 2000 mass spectrometer. Samples were injected
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cold-on-column using helium as carrier gas, and after separation on an Agilent FFAP
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capillary column (30 m × 0.32 mm i.d., 0.25 μm film thickness) in the first dimension the
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substance of interest was transferred via MCSS into a cold trap (-100 °C) and via heating
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to an Agilent DB5 capillary column (30 m x 0,25 mm i.d., 0,25 µm film thickness). The
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temperature program of the first GC was as follows: 40 °C held for 2 min, 6 °C/min up to
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230 °C, and finally held for 5 min. The second GC started the following temperature
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program directly after the transfer of the effluent from the cooling trap at 40 °C, 6°C/min
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to 240 °C, held for 3 min. The intervals of the cut times were set after an initial analysis of
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reference compounds. The mass spectrometer was operated in the MS-CI mode using
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methanol as reactant gas. -9-
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Comprehensive
two-dimensional
GCxGC-TOF-MS.
The
system
(LECO;
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Mönchengladbach, Germany) consisted of a Gerstel PTV 4 injector (Mühlheim an der
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Ruhr, Germany), a PAL autosampler (CTC-Analytics), an Agilent 6890N gas
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chromatograph with a secondary oven mounted inside the primary GC oven and a
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Pegasus 4D TOF-MS. The samples were injected cold-on-column (1-2 µL) and helium
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served as carrier gas. The separation in the first dimension was performed with an Agilent
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DB-FFAP capillary (30 m × 0.32 mm i.d.; 0.25 μm film thickness) using the following
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temperature program: 40 °C held for 2 min, 6 °C/min up to 230 °C, held for 5 min. A two-
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stage modulator for cryogenic temperatures with a 4 s modulation time transferred the
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effluent continuously onto the second column, an Agilent DB17-MS-capillary (2.2 m x 0.18
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mm i.d., 0.18 µm film) having permanently a 20 °C higher oven temperature compared to
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the first column oven. The characteristic ions were monitored in the electron ionization
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mode (MS-EI, 70 eV), measured with a frequency of 100 scans/s. Data obtained were
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evaluated using the software GC-Image (version 2.1, Lincoln NE, USA).
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LC-MS/MS measurements.
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For amino acid quantitation, a Thermo Finnigan Surveyor HPLC-system (Egelsbach,
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Germany) coupled to a triple-stage quadrupole mass spectrometer (TSQ Quantum,
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Thermo Finnigan) was used. Chromatographic separation was performed on a Synergi
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Hydro RP column (150 × 2 mm, 4 μm, 8 nm, Phenomenex, Aschaffenburg, Germany)
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using the following conditions: solvent A, FA (0.1%, v/v) in water, solvent B, FA (0.1%,
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v/v) in acetonitrile; gradient, 0−1 min 0% B, 1-1.1 min 0-15 % B, 1.1-20 min 15−35% B,
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20−25 min 35-40% B, 25−29 min 40-90 % B, 39-36 min 90% B; flow rate, 0.2 mL/min; - 10 -
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injection volume, 10 μL; column temperature, RT. The ion source was operated in the ESI
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positive mode using the following source parameters: spray voltage, 4000 V; sheath gas
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pressure, 35 arbitrary units (au); aux gas pressure, 15 au; capillary temperature, 320 °C.
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By means of multiple reaction monitoring (MRM), characteristic transitions from precursor
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to product ions of each benzoylated amino acid were measured using experimentally
238
optimized collision energies (Table 2).
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Sensory analysis. Sensory experiments were performed by a trained panel of 15-20
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persons (male and female, aged 22 to 58 years) who had participated at weekly sensory
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training sessions. Tests were organized in a sensory room with individual sections for
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each panelist at RT and white light. Odor detection thresholds in starch were determined
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as previously reported.24 Aroma compounds were added to 50 g of corn starch either
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directly or dissolved in 50 µL water containing less than 10 mg/L ethanol and shaken in a
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3D-shaker (Willy A. Bachofen AG, Muttenz, Switzerland) for 15 min. Reference starch
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samples for the triangle tests were treated analogously by adding the same amount of
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water.
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Standard determinations. The water contents of the flours were determined thermo-
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gravimetrically using an infrared moisture analyzer (MA35M, Sartorius AG, Goettingen,
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Germany) according to the literature.25 Bread crumbs were homogenized as detailed in
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the sample work up for aroma compound quantitation. The water content of the yeast was
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determined by the mass difference before and after freeze drying.
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Statistical data treatment. For the calculation of mean values and standard deviations
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of triplicates Microsoft Office Excel 2013 (Microsoft Corporation, Seattle, Washington,
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USA) was used.
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RESULTS AND DISCUSSION
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Differences in the aroma compounds of rice and wheat bread.
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Recently,10 36 to 42 different aroma active compounds were identified by means of AEDA
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in the crumb and crust of rice and wheat bread respectively. Among these, 18 odorants
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were quantitated in samples prepared as recently reported. The selection criteria were
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either a high FD factor (FD ≥1024) in one or both bread samples or an expected significant
266
difference of this aroma compound between wheat and rice bread (three or more FD
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factors difference, FD ≥128). Additionally, acetic acid was analyzed because of its
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difference in the FD factors between rice bread and rice flour. Hexanal and (Z)-2-butyl-2-
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octenal were estimated to be important aging indicators. Some crust aroma compounds
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reported in previous studies such as Strecker aldehydes and 2-acetyl-pyrroline didn’t meet
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the criteria and were, therefore, not quantified.
272 273
In the wheat bread crumb and crust (Table 3) the highest contents were determined for
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acetic acid (> 10 mg/kg), followed by 2-phenylethanol and 3-methyl-1-butanol (> 1 mg/kg),
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2- and 3-methylbutanoic acid and 2-methyl-1-butanol (0.5-1 mg/kg). The contents of these
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yeast metabolites and of (E,E)-2,4-decadienal were higher in wheat bread crumb
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compared to the crust. However, maltol showed significantly higher concentrations in the
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crust (7472 µg/kg) than in the crumb (45 µg/kg), as well as acetic acid, 2-methoxy-4-
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vinylphenol and (E)-2-nonenal. In general the results were in agreement with the AEDA - 12 -
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data of our previous study,10 and also agreed with previously published data on the aroma
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of wheat bread.26–30
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Next, OAVs were calculated for each compound. In wheat bread crumb and crust, 13 or
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12 substances, respectively had an OAV of 1 or higher (Table 3). 3-Methylbutanoic acid
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and 3-methyl-1-butanol were most relevant in the crumb, followed by 2-methoxy-4-
286
vinylphenol, phenylacetic acid and 2-methyl-1-butanol. The ranking of aroma compounds
287
for bread crumb and crust did not differ considerably, but the leucine metabolites were
288
more relevant in the crumb, while 2-methoxy-4-vinylphenol was of higher importance in
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the crust. Furthermore, maltol with a caramel-like aroma reached an OAV of 5 in the wheat
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bread crust.
291 292
Similar to wheat bread, acetic acid and the yeast metabolites also reached the highest
293
contents in the rice bread samples made from the fresh flour batch R1 (Table 4). The rice
294
bread crumb contained higher amounts of 3-methyl-1-butanol, 2-phenylethanol and 2-
295
methyl-1-butanol as well as (E,E)-2,4-decadienal than the crust. In contrast, higher
296
contents of 3-methylbutanoic acid, phenylacetic acid, maltol and of the lipid oxidation
297
products from linoleic acid31 (E)-2-nonenal and 1-octene-3-one, which are known to be
298
characteristic for the bread crust aroma,30 were present in rice bread crust.
299 300
Out of the 18 aroma compounds quantitated in the rice bread, 10 reached an OAV 1 in
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the crumb and 9 in the crust (Table 4). In both, the crumb and the crust 3-methyl-1-butanol,
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3-methylbutanoic acid, acetic acid, 2-methoxy-4-vinylphenol and phenylacetic acid
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showed the highest OAVs. The OAVs confirmed the higher relevance of 3-methyl-1- 13 -
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butanol and 2-phenylethanol for the aroma of rice bread crumb and of 1-octene-3-one,
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acetic acid and phenylacetic acid for the aroma of the crust.
306 307
In general, rice bread samples differed from wheat bread samples due to significantly
308
higher contents of 2-aminoacetophenone, acetic acid (> 400 %) and 4- vinylphenol
309
(> 200 %) and significantly lower amounts of (E)-2-nonenal, hexanal, (E,E)-2,4-
310
decadienal, maltol (< 25 %) and -nonalactone (< 50 %) (Tables 3 and 4). Compared to
311
wheat, the rice bread crumb contained higher levels of alcohols known to be formed by
312
the metabolic activity of yeast, in particular 3-methyl-1-butanol, and lower concentrations
313
of 2- and 3-methylbutanoic acid. A partially opposite, but less pronounced difference was
314
found for the bread crusts. 1-Octene-3-one had higher and 2-methoxy-4-vinylphenol had
315
lower concentrations in the rice bread crust than in the wheat bread crust. The impact of
316
these differences on the overall aroma can be derived from a comparison of OAVs (Tables
317
3 and 4). Accordingly, 2-aminoacetophenone (grape-like, medicinal) is characteristic for
318
rice bread since its concentrations in wheat bread samples were below the odor detection
319
threshold. This odorant is known as a key aroma compound of cooked rice occurring in
320
concentrations of 0.8-1.5 µg/kg (up to 5 µg/kg dry matter).22 The concentrations in the rice
321
bread samples strongly exceeded the literature data. In addition, 3-methyl-1-butanol in
322
rice bread crumb, 3-methylbutanoic acid and 1-octene-3-one in rice bread crust as well
323
as acetic acid in both can be suggested to be responsible for the differences to wheat
324
bread. The grassy, green and fatty smelling aldehydes hexanal, (E)-2-nonenal and (E,E)-
325
2,4-decadienal only reached relevant OAVs in the wheat bread samples, the caramel-like
326
maltol and the smoky, clove-like 2-methoxy-4-vinylphenol reached much higher OAVs in
327
the wheat bread crust than in rice bread crust. - 14 -
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Formation of aroma compounds by yeast metabolism.
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Since the same type and amount of yeast was used for rice and wheat bread making, it
331
was assumed that differences in aroma compounds formed by yeast were caused by
332
differences in the amino acid composition of the raw materials. Therefore, the contents of
333
the free amino acids isoleucine, leucine and phenylalanine, the precursors of 2- and 3-
334
methylbutanol, 2-phenylethanol and their corresponding acids, were determined. The
335
contents differed significantly between rice flour, wheat flour and yeast (Figure 1). The
336
concentrations of amino acids in wheat flour confirmed previous results of Opperer32. But,
337
compared to wheat flour, rice flour contained only 3-13 % of each free amino acid, and in
338
particular, the isoleucine content was comparatively low. However, yeast could be
339
considered as an important source of amino acids even though its percentage in the
340
dough was very low (about 5.4 mg yeast dry matter/kg dough).
341 342
During soaking the free amino acid contents in the wheat flour suspension was increased
343
by 266%, 184% and 175% for leucine, phenylalanine and isoleucine (Figure 2 A). This
344
might have been the result of peptidases activated in the presence of water as described
345
for rice kernels by Saikusa et al..33 In contrast, no relevant increase of the free amino acid
346
content was observed for rice flour after soaking. Obviously, the enzymatic activity of the
347
rice flour was very low and indicated a low content of the enzyme-active pericarp fraction
348
in the flour.33
349 350
The amino acid contents of yeasted doughs as affected by the fermentation time are
351
shown in Figure 2 B. During mixing of wheat dough, the release of free amino acids in - 15 -
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wheat flour exceeded the consumption by yeast so that the initial contents of leucine and
353
phenylalanine increased slightly. The isoleucine content remained constant. The higher
354
temperature during the subsequent fermentation increased the yeast activity and a decline
355
of all amino acids was observed. In contrast to wheat dough, the amino acid supply in the
356
rice dough was lower, and there was no release of free amino acids from the rice flour
357
during soaking. This resulted in a very fast decline of 50 % of the amino acids after mixing
358
and of 75 % after the first quarter of fermentation, but not in a total metabolization.
359 360
The data enabled the calculation of the total available free amino acid concentrations in
361
the doughs and the comparison with the content of aroma-active yeast metabolites in the
362
bread crumbs. The contents based on dry matter (wheat flour: 86.4%; rice flour: 88.6%,
363
wheat bread crumb: 56.5 %, rice bread crumb: 51.7 %) are shown in Figure 3. In wheat
364
dough (Figure 3 A) the availability of leucine was higher than of isoleucine and
365
phenylalanine resulting in higher amounts of leucine metabolites in the wheat bread
366
crumb. However, metabolic rates of all amino acids were below 50 %. As described in the
367
literature, a preferred formation of the alcohol was observed for all amino acids.14,32 The
368
rice-based model dough (Figure 3 B) gave opposite results. Although the contents of free
369
amino acids were similar, considerable differences in the concentrations of the
370
metabolites were determined. Especially high amounts of 3-methyl-1-butanol and 2-
371
phenylethanol were determined in the rice bread crumb exceeding the amount of available
372
precursors. Thus, alternative pathways of amino acid release might exist in the rice dough
373
model. Possibly, the nutrient deprivation in the rice dough system caused an increase of
374
the proteolytic activity of yeast enzymes.34,35 This might also explain the remaining free
375
amino acid concentrations in the rice dough at the end of fermentation (Figure 2 B). - 16 -
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376 377
Retention of aroma compounds from rice flour in rice bread.
378
To investigate the retention of aroma compounds from rice flour to rice bread, the contents
379
of 12 selected substances were determined in the fresh rice flour R1 (Table 5). Compared
380
to the analysis of bread, the Ehrlich Pathway products that were formed during dough
381
fermentation were not considered in the flour. The overall aroma intensity of the rice flour
382
was low and only four compounds reached an OAV > 1. Acetic acid (OAV 42) occurred
383
with the highest concentration and OAV in the rice flour followed by hexanal (OAV 2). For
384
both compounds, and additionally for (E)-2-nonenal (OAV 1) and (Z)-2-butyl-2-octenal,
385
lower contents were determined in the rice bread samples (Table 4) so that a retention of
386
these aroma compounds can be assumed. 1-Octene-3-one (OAV 2) had a similar
387
concentration in the flour and the bread. Although the other odorants occurred in lower
388
concentrations in the flour than in the bread, all of them were detectable in the flour.
389 390
Influence of the rice flour age on the rice bread aroma compounds
391
In our previous study we have shown a high impact of storage of rice flour on the bread
392
aroma. To verify this result, 10 relevant bread aroma compounds were quantitated in the
393
stored rice flour R2 and the corresponding bread produced thereof (Table 6). In general,
394
all aroma compounds had higher concentrations in the stored flour R2 and in the bread
395
(Table 6) compared to the flour and bread from R1 (fresh) (Tables 4 and 5). The stored
396
rice flour R2 yielded a bread crumb with 40-66% higher concentrations of the Ehrlich
397
pathway products of leucine and isoleucine, i.e., 2- and 3-methyl-1-butanol, compared to
398
bread crumb prepared from flour R1. The alcohol levels were more than 100 % higher in
399
the crust of the R2 (stored) bread than in that of R1 (fresh) (Tables 4 and 6). This points - 17 -
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400
to proteolytic activity in the flour that may lead to a degradation of the flour protein to
401
peptides and free amino acids during storage. This assumption is supported by data of
402
Dhalwali et al. who studied the storage behavior of milled rice and reported an increase
403
of proteolytic activity and free amino acid contents.36 In fact, the contents of free leucine
404
and isoleucine in the stored flour R2 were only slightly higher than in R1 (data not shown).
405
Upon storage of rice flour, lipid oxidation products, especially hexanal, -nonalactone and
406
(Z)-2-butyl-2-octenal showed the greatest changes. In particular (Z)-2-butyl-2-octenal had
407
a more than 90-fold higher content in the stored rice flour R2 than in the fresh flour R1.
408
The low retention rate of this compound from flour to bread was probably due to its higher
409
reactivity. Consequently, this substance can be seen as an important aging indicator.
410
Furthermore, (E,E)-2,4-decadienal and vanillin concentrations increased in flour upon
411
storage and can also be considered as indicators of storage. The higher concentrations
412
of these compounds in the stored flour R2 were retained in the respective breads.
413 414
Table 6 contains the OAVs of the aroma compounds in rice flour R2 and in the
415
corresponding bread crumb and crust. The data showed that not all substances formed
416
during storage had an influence on the overall aroma. 3-Methyl-1-butanol and 3-
417
methylbutanoic acid showed the highest OAVs in the crumb and crust from the stored rice
418
flour R2. However, the OAVs of the isoleucine yeast metabolites did not differ between
419
the rice breads made from different aged flour. (Tables 4 and 6). Hexanal, which had an
420
OAV 1 for (E,E)-2,4-decadienal (crumb and crust) and for (E)-2-nonenal (crumb) in the
426
rice bread samples of R2.
427 428
The data on the differences between the aroma compounds of rice and wheat bread
429
crumbs and crusts are the basis for the optimization of bread quality prepared from gluten-
430
free ingredients. Since the aroma of the rice flour itself was very weak, systematic changes
431
of the bread manufacturing process would be a promising tool to regulate the formation of
432
desired odorants and to avoid off flavors. Also, additives increasing the Maillard reaction
433
might improve the aroma of the rice bread crust. Furthermore, the flour age was found to
434
be an important factor for the sensory quality of rice bread. Because 2-
435
aminoacetophenone, a characteristic aroma compound of the rice bread, was not present
436
as odor-active compound in wheat bread, it can be assumed to be an off-flavor compound.
437
To confirm this assumption, further studies are underway.
438 439
ACKNOWLEDGMENT
440
This IGF project of the FEI was supported via AiF within the program for promoting the
441
Industrial Collective Research (IGF) of the German Ministry of Economics and Energy
442
(BMWi), based on a resolution of the German Parliament. Project CORNET AiF 147 EN
443
“GLUeLESS”. The authors wish to thank Stefanie Hackl for her excellent technical
444
assistance and Patrick Roehrl for carrying out the amino acid analyses.
445
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ABBREVIATIONS USED
447
CI, chemical ionization; EI, electron ionization; FA, formic acid, FD, flavor dilution; FID,
448
flame ionization detector; OAV, odor activity value; RI, retention index; RT, room
449
temperature; SAFE, solvent assisted flavor evaporation; SIDA, stable isotope dilution
450
analysis
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(35) Bernreuther, D. Untersuchungen Zur Autophagocytose in Der Hefe Klonierung Und Charakterisierung Des SAI1 -Gens, Dissertation, Universität Stuttgart, 2002. (36) Dhaliwal, Y.; Sekhon, K.; Nagi, H. Enzymatic Activities and Rheological Properties of Stored Rice. Cereal Chemistry. 1991, pp 18–21. (37) Widjaja, R.; Craske, J. D.; Wootton, M. Changes in Volatile Components of Paddy,
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Brown and White Fragrant Rice during Storage. J. Sci. Food Agric. 1996, 71 (2),
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FIGURE CAPTIONS
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Figure 1 Contents of the free amino acids leucine (Leu), isoleucine (Ile) and phenylalanine
568
(Phe) in wheat flour (black), rice flour (R1, light grey) and yeast (dark grey) based on dry
569
matter. Standard deviations (n = 3) are given as error bars.
570 571
Figure 2 Relative changes of leucine (___), isoleucine (……) and phenylalanine (_ _)
572
contents of wheat (black) and rice flour R1 (light grey) during soaking (A) and of their
573
corresponding yeast doughs during fermentation (B). The timelines include the mixing
574
time (6 min), therefore the data points at 0, 10, 20, 30 and 40 min of fermentation are
575
shifted to the right by 6 min. Standard deviations (n = 3) are given as error bars.
576 577
Figure 3 Comparison of free amino acid contents of doughs (black) and of the resulting
578
contents of yeast metabolites (alcohols: light grey; acids: grey) in the crumb of wheat
579
bread (A) and rice bread (B) based on dry matter. Standard deviations (n = 3) are given
580
as error bars.
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TABLES Table 1 Standard substances, labels, mass traces and calibration curves used in the stable isotope dilution assays for aroma compound quantitation substance
label Ionization mass trace (m/z) analyte standard a hexanal d12 CI 101 113 a 3-methyl-1-butanol d2 CI 71 73 b 1-octene-3-one d2,3 CI 127 129,130 b (E)-2-nonenal d2 CI 123 125 c (Z)-2-butyl-2-octenal d20 EI 139 152 a 3-methylbutanoic acid d9 CI 117 126 a (E,E)-2,4-decadienal d4,5 CI 153 157,158 b 2-phenylethanol d4,5 CI 105 109,110 13 a maltol C2 EI 126 128 13 c -nonalactone C2 EI 85 87 13 c 2-methoxy-4C6 EI 150 156 vinylphenol 2-aminoacetophenone d3 EIc 135 138 c 4-vinylphenol d4 EI 120 124 13 c phenylacetic acid C2 EI 136 138 13 c vanillin C6 EI 151 157
calibration curve slope intercept R2 0.965 -0.119 0.999 1.137 -0.023 1.000 0.723 -0.019 1.000 0.848 -0.008 1.000 0.898 -0.085 0.992 0.917 0.011 0.995 0.893 -0.051 1.000 0.873 0.029 0.999 1.489 -0.086 0.995 0.866 0.086 0.995 0.875 0.116 0.991 0.916 1.268 1.050 1.230
0.013 -0.078 -0.050 0.029
0.997 0.999 1.000 0.997
analysis using the HRGC-MS system; b analysis using the 2D “heartcut”-GCxGC-MS system; c analysis using the GCxGC-TOF-MS system; CI, chemical ionization using methanol as reaction gas; EI, electron ionization (70 eV) a
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Table 2 Multiple reaction monitoring (MRM) transitions and calibration curves for amino acid quantitation by LC-MS/MS amino acid leucine
label
MRM transitionsa
-
236.1 → 105.1 (18 V) 236.1 → 190.1 (8 V) 242.1 → 105.1 (18 V) 242.1 → 195.1 (8 V) 236.1 → 105.1 (18 V) 236.1 → 190.1 (8 V) 242.1 → 105.1 (18 V) 242.1 → 195.1 (8 V) 270.1 → 105.1 (18 V) 270.1 → 224.1 (8 V) 275.1 → 105.1 (18 V) 275.1 → 229.1 (8 V)
13C
isoleucine
6
13C 6 phenylalanine d5 a Characteristic
calibration curve slope intercept R2 0.783 0.038 1.000 0.820
0.045
1.000
1.061
0.053
1.000
MRM transitions, quantifiers are given in bold, fragmentation potentials are given in
parentheses
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Table 3 Concentrations, odor thresholds (OT) and odor activity values (OAV) of selected aroma compounds in wheat bread crumb (WBb) and crust (WBt) odorant 3-methylbutanoic acid 3-methyl-1-butanol 2-methoxy-4-vinylphenol phenylacetic acid 2-methylbutanoic acid 2-phenylethanol 1-octene-3-one acetic acid hexanal (E)-2-nonenal (E,E)-2,4-decadienal 2-methyl-1-butanol vanillin maltol 2-aminoacetophenone -nonalactone 4-vinylphenol (Z)-2-butyl-2-octenal
concentration [µg/kg]a OTb WBb WBt [µg/kg] 900.00 622.00 13.00 2711.00 1509.00 78.00 74.00 113.00 4.60 330.00 302.00 23.00 1016.00 638.00 77.00 2715.00 1712.00 470.00 0.90 0.99 0.23 97863.00 154199.00 30000.00 111.00 132.00 42.00 19.00 32.00 12.00 102.00 33.00 48.00 899.00 553.00 763.00 336.00 167.00 440.00 45.00 7472.00 1400.00 1.30 n.d. .0 2.90 96.00 72.00 3300.00 15.00 18.00 2100.00 d n.d. n.d.d 5400.00
a mean
OAVc WBb 69 35 16 14 13 6 4 3 3 2 2 1 1 .00