Abstract
In this study, we sourced 37 commercial flours from 14 mills based on 7 countries and analysed them with a total of 18 methods, generating 90 single analytical values for each flour. The 18 methods were chosen to cover the analytical practice of most European mills and bakery companies, as well as particle charge detection, GlutoPeak and solvent retention capacity as emerging methods. We investigated the relationship between the data from the individual methods, and performed a principal component analysis to describe the structure of the data set and identify the main underlying flour properties. Four principal components accounted for 64.8% of the total variance. They were interpreted as (PC1) starch gelatinization properties, (PC2) hydration properties, (PC3) dough resistance at variable water amount, and (PC4) dough strength at fixed water amount. From the emerging methods, solvent retention capacity (sodium carbonate and water) was highly correlated with PC2, while the GlutoPeak max torque was highly correlated with PC4.
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Introduction
Both industrial and craft bakeries are facing the problem of variability of wheat flour quality. This variability makes it impossible to bake over a longer period of time with constant recipes and constant process parameters. To be able to react pro-actively to flour quality variations, bakery companies need reliable analytical methods that allow predicting the behaviour of flour in production as well as the final bakery results. In practice, flour analysis is usually performed in the mill; bakery companies rely on values provided on analytical certificates, which typically include 5–10 parameters.
In this context, millers and bakers need to agree on a set of measurements that is practicable in daily production and delivers the most useful information. Interestingly, across Europe, the analytical practice differs depending on the countries. In UK and Ireland, for example, the level of damaged starch is considered to be of high importance for functionality. In France and Spain, AlveoLAB measurements are considered as a standard. In Germany, Farinogram measurements are common. One could argue that the reason for this different practice lies in different applications (local bread recipes), but a part of the explanation certainly lies in historical reasons, habits, and the continuous use of equipment already available in the mills.
Globalization of wheat commerce, modification of wheat quality related to climate change [5, 22], evolution in bakery production practice (industrialisation, increasing use of freezing technology [3, 9]), change in consumption habits, and the availability of novel flour analysis methods are good reasons for questioning the flour analytical practice.
In this study, our goal was to compare and better understand the information provided by different flour analysis methods used across Europe, including both established and emerging methods. To this end, we analysed 37 commercial flours from 14 mills located in 7 European countries by 18 different methods, generating 90 analytical values for each flour. The similarities and differences of the data obtained by the different methods were evaluated by statistical techniques.
Table 1 gives an overview of the methods used in our study. Some methods quantify the amount of specific flour components (water, minerals, protein, acids, and damaged starch), while other characterize the functionality of gluten, starch, pentosans, and alpha-amylases. The table gives an evaluation of the level of skills required, the price category of the equipment, the workload per sample, and the analysis time.
Experimental
Raw materials
37 wheat flours (50 kg of each) were sourced from 14 European mills located in Belgium, France, Germany, Italy, The Netherlands, Spain, and the United Kingdom. The flours were specified regarding their ash content (0.50–0.65 after ICC 104), their protein content (min 11.0 after ICC 167), and their moisture content (max. 16.0 after ICC 110/1). In some countries, it is usual to add some substances to the flour in the mill during production (e.g., gluten, enzymes, malt flour, vitamins, and minerals). Our flours were packed without these additions at our demand. The only additive we accepted was ascorbic acid, which is used widely across Europe and was contained at concentrations between 0 and 25 ppm in the assessed flours.
Analytics
All 37 flours were analysed by a series of methods that were selected to reflect the diversity of analytical approaches commonly used by millers and bakers across Europe. The corresponding ICC and AACC standards are mentioned in Tables 1 and 2. The selected methods included moisture, ash, protein, wet and dry gluten, and damaged starch content as well as pH and acidity. Furthermore, functionality assessment was performed with the established methods sedimentation value, falling number, Brabender (Duisburg, Germany) Farinograph, Extensograph and Micro Visco Amylograph, Chopin (Villeneuve-la-Garenne, France) Mixolab, AlveoLAB and Rheo F4, as well as Perten (Hägersten, Sweden) Glutomatic and Rapid Visco Analyser. Finally, the following emerging methods and devices were used: Brabender GlutoPeak, Chopin SRC-CHOPIN, and BTG (Eclépens, Switzerland) Mütek PCD-05. GlutoPeak is a gluten aggregation test, giving an indication of the gluten strength (aggregation energy GPG) and of the speed of aggregation (time of maximum torque GPT). Several authors reported correlations of the GlutoPeak values with Alveograph, Extensograph, and Farinograph values [18, 10] and with the level of protein and gluten [19]. Compared to those methods, the main advantages of GlutoPeak are the speed of analysis and the lower price of the device. With the SRC-CHOPIN based on the solvent retention capacity method [14], the functionality of gluten, pentosans and damaged starch, as well as flour hydration can be investigated in one device. Particle charge detection investigates the electrical load of macroions in a flour suspension and represents a different, innovative approach to flour functionality [21].
A code was assigned to each parameter, as shown in Table 2. For each flour, all analytical investigations were performed within 2 weeks, to exclude as far as possible the influence of quality change over time (as described in [8]) on the correlations observed. The acid ascorbic content ASA as declared by the mills was also included into the data set.
Data analysis
The Pearson’s correlation coefficients relating the individual parameters were calculated, with the corresponding P values. The structure of the data set was further investigated by carrying out a principal component analysis with a Varimax rotation on four principal components. All calculations were performed using IBM SPSS Statistics version 22.
Results
Overview of data
Table 2 gives an overview of the data obtained, with the minimum and maximum values observed for each parameter, the average, and the relative standard deviation. Some values were found to be slightly out of our specification, but we chose to keep the corresponding samples in the evaluation, as they represent the quality available on the market.
Observed correlations
Table 3 gives all correlation coefficients with an absolute value superior or equal to 0.7 and a P value below 0.001, which were calculated between parameters generated by different methods. Table 4 gives the results of the PCA, whose four first principal components account for 64.8% of the variance in the data set. Figures 1, 2 show loadings plots of the single analytical parameters on the four principal components. In the following, the main relationships observed are described following the structure given by the PCA.
The first principal component is related to rapid visco analyser values (peak viscosity VAM, holding viscosity VAY, setback viscosity VAS, and final viscosity VAV), micro visco amylograph values (viscosity at start of cooling MVD, viscosity at start of holding MVC, hot viscosity MVB, and cold viscosity MVE), Mixolab values (C4 torque X4D, C5 torque X5D, C4 time X4T, and stability XST), and the falling number FAN. Referring to Table 3A, the rapid viso analyser values have strong and significant correlations both with the falling number FAN and the Mixolab C4 and C5 torque X4D, X5D and C4 time X4T.
The second principal component is related to solvent retention capacity values (calcium carbonate SRC, water SRW), the level of damaged starch DST, some AlveoLAB values (extensibility AVL, AVG, ratio AVR, and tenacity AVP), Mixolab hydration XHY, Rheo F4 gaseous release RGC and RGS, particle charge at 4 min of swelling P04, and the temperature at start of gelatinization from the micro visco amylograph MTA and the rapid visco analyser VAP. Referring to Table 3B, the SRC water value SRW correlates with some PCD values (P04, P24), the damaged starch level DST, the Mixolab hydration value XHY, the AlveoLAB tenacity AVP and ratio AVR, and the pasting temperature VAP as measured by the rapid visco analyser. The solvent retention capacity calcium carbonate value SRC correlates with all the previous ones and the AlveoLAB AVL and AVG values. Next to this, the Mixolab hydration value XHY correlates with the Farinograph water absorption FWA as well as with all AlveoLAB values. The Farinograph water absorption FWA also correlates with the dough tenacity AVP as measured by the AlveoLAB.
The third principal component is almost solely related to some Extensograph values (resistance ER45, ER90, and ER135, resistance maximum EM45, EM90, and EM135, ratio resistance/extensibility EY45, EY90, and EY135, and ratio resistance maximum/extensibility ED45, ED90, and ED135), only with the amount of ascorbic acid ASA also having a high value on it (above the threshold of 0,7). Referring to Table 3C, the amount of ascorbic acid ASA is related to the Extensograph ratio values ED90, ED135, and EY135.
The fourth principal component is related to further AlveoLAB values (baking strength AVW and index AVI), the protein content PRT, the Extensograph extensibility at 45 min EX45 and the GlutoPeak max torque GPM. Referring to Table 3D, the AlveoLAB baking strength AVW and index AVI correlate with the protein content PRT. The baking strength AVW also correlates with the GlutoPeak max torque GPM.
In addition to the structure given by the principal component analysis, Table 3D presents further interesting correlations. Indeed, the AlveoLAB baking strength AVW is also related to the Extensograph energy values EE45, EE90, and EE135, the GlutoPeak torque at maximum GPM, and torque after maximum GPA. The AlveoLAB index value AVI also correlates with the Extensograph energy and maximum values EE45, EE90, EE135, EM90, and EM135. Furthermore, the AlveoLAB tenacity AVP is related to the GlutoPeak start energy GPA, aggregation energy GPS, and torque after maximum GPG. Next to this, the SRC lactic acid value SRL correlates with the sedimentation value SDV. The Farinograph and Mixolab hydration values FWA and XHY correlate with the GlutoPeak start energy GPS, aggregation energy GPG, and torque after maximum GPA. Finally, the dry gluten GMD as determined with the Glutomatic correlates with the protein content PRT.
Other relationships are described in Table 3E: The Farinograph stability FST correlates with the AlveoLAB baking strength AVW, the Mixolab stability XST, and the Mixolab C2 torque X2D. The Farinograph dough-softening FDS correlates negatively with the Mixolab stability XST and the Mixolab C2 torque X2D. The Farinograph quality value FQV is related to the Mixolab stability XST, the Mixolab C2 torque X2D, and the Mixolab C1 time X1T.
Parameters without significant correlations
It is remarkable that the ash content ASH, the pH value PH, the acidity ADT, most of the Rheo F4 values, and the Gluten Index GMI and Wet Gluten GMW level were found to have no high and significant correlations with the other parameters measured. This indicates that these parameters are, to a certain extent, independent from the other flour properties.
Discussion
Starch gelatinisation and viscosity
PC1 is related to starch gelatinisation and viscosity. The methods rapid visco analyser, micro visco amylograph, Mixolab, and falling number are all based on forming a starch gel by following a temperature cycle in the presence of water. The measured viscosities are mainly related to starch gelatinization, starch degradation by endogenous alpha-amylases and starch retrogradation. Similar correlations were reported by Deffenbaugh and Walker [6] (RVA vs. micro visco amylograph) as well as Peña and Posadas-Romano [20] (Mixolab C4 and C5 vs. Falling number).
No relation with analytical values describing gluten was observed on PC1 (at the threshold of 0,7), suggesting that the viscosity values represented on this principal component are mainly influenced by starch, not gluten.
In summary, a high score on PC1 indicates a high viscosity after gelatinization, which may be related to a low alpha-amylase activity. PC1 can be best assessed by the micro visco amylograph and the rapid visco analyser.
Water absorption and dough plasticity/elasticity at fixed water amount
PC2 describes water absorption and the dough plasticity/elasticity ratio at fixed water amount. The level of damaged starch, as assessed by the SDmatic (DST) and the SRC sodium carbonate value (SRC), has a strong influence on hydration, as assessed by the SRC water value (SRW), and the Mixolab and Farinograph hydration values (XHY, FWA). Similar results were obtained by Hammed et al. [11].
It is, furthermore, well understandable that the hydration is related to the plastic/elastic characteristic of the dough, as assessed with the AlveoLAB: the higher the level of water binding (by the starch but also by the gluten and the pentosans), the dryer the dough will be, which results in a lower extensibility (AVL, AVG), and a higher resistance to deformation (AVP), increasing the ratio P/L (AVR). This applies to the AlveoLAB measurement as it is performed with a fixed amount of water according to ICC 121, and is consistent with the results reported by Van Bockstaele et al. [23] and Li et al. [15]. The Extensograph measurement, on the contrary, is performed with a variable amount of water according to ICC 114/1, which probably explains why its values are not found on PC2.
The observed correlation of the RVA pasting temperature VAP with the SRC sodium carbonate (SRC) is in line the results of Barak et al. [2], Yu et al. [24], and Ma et al. [17] stating a correlation with the level of damaged starch, and can be interpreted as an earlier pasting in case of better hydration of the starch granules.
It is interesting that the SRC water and sodium carbonate values (SRW, SRC) are related to the PCD total charge after 4 and 24 min (P04, P24). Longin et al. [16] already observed this phenomenon on emmer flours. This suggests that a higher (negative) charge of the macroions in the dough leads to a higher water binding.
A high score on PC2 indicates a low water absorption, a low level of damaged starch, and a high dough extensibility at fixed water amount. PC2 can be well assessed by the measurement of the SRC values, the level of damaged starch, and the AlveoLAB extensibility.
Dough resistance at variable water amount
PC3 is related to dough resistance as measured with the Extensograph. PC3 shows that doughs that are standardized to a certain firmness (500 BU) by varying the amount of water in the Farinograph will still, after a resting time of 45, 90, and 135 min, have a different resistance to deformation (ER45, EM45, ER90, EM90, ER135, and EM135). As there is no relation of PC3 to the extensibility values, it is probable that the observed correlation with the ratio values EY45, ED45, EY90, ED90, EY135, and ED135 is only related to the resistance values.
Remarkably, the amount of ascorbic acid has a high correlation with the ratio values ED90, ED135, and EY135, which indicates that the addition of ascorbic acid favours elastic properties (resistance to deformation) at the expense of plastic properties (extensibility). This is consistent with the data of [1, 7].
A high score on PC3 indicates a high resistance to deformation of dough at variable water amount. It can be well assessed with the Extensograph and can be, to a certain extent, influenced by the addition of ascorbic acid.
Dough strength at fixed water amount
PC4 describes dough strength, i.e., the combination of elastic and plastic properties, as measured by the AlveoLAB at fixed water amount. This property is related to the protein content and the GlutoPeak torque values (GPA, GPM). The latter is in line with the findings of Marti et al. [19], who developed correlation models to predict AlveoLAB values from GlutoPeak measurements.
A high score on PC4 indicates a high dough strength at fixed water amount. It can be well assessed with the AlveoLAB.
Other correlations
It is interesting that the AlveoLAB dough strength (AVW) is related to the Extensograph energy values (EE45, EE90, and EE135). Both values are based the same concept (combination of resistance and extensibility measured when stretching dough); despite the differences between both measuring systems (inflating a bubble of dough vs. stretching a dough piece) and the differences of water amount (fixed vs. variable), the values are still correlated—unlike the other values determined by AlveoLAB and Extensograph.
The correlations found between the values measured by the Farinograph and the Mixolab confirm previous findings, e.g., from [4, 13]. The correlation between the hydration values and the GlutoPeak values suggests that a stronger gluten will bind more water. This in line with the data of Marti et al. [19] and Fu et al. [10].
The absence of strong correlation between the level of gluten (wet and dry) and the measured functional values suggest that in our flour samples, the quality of the gluten was highly variable. This can be explained by our deliberate choice to use commercial flours from very various origins.
Conclusions
Our results highlighted the importance of the following properties in wheat flour analysis: starch gelatinization, hydration, dough resistance at variable water amount, and dough strength at fixed water amount. These results may be of interest for millers and bakers when it comes to selecting methods appropriate to describe quality in an effective yet comprehensive manner. It seems indeed advisable to use at least one method from each of the four groups defined by the principal components. Several options are available regarding the choice of instruments. On the contrary, it probably makes less sense to use two methods which results are highly correlated to one another. It is to be noted that, as flour processing companies will hardly invest in both an AlveoLAB and an Extensograph, the possibility to work with a single instrument at both fixed and variable water amount should be explored.
Similarly, we suggest that research teams may use our results to select the most appropriate setting of instruments to characterize their wheat flours—although this may result in a different selection of instruments than in processing companies, as the time of analysis may be less relevant.
The values assessed by the emerging methods SRC (as performed with the SRC-CHOPIN) and Brabender GlutoPeak show to have high correlations with established methods. This suggests that these methods do not assess new properties of flour, but rather represent an alternative to established methods—especially considering that they are faster and that they may be more cost effective.
As far as the baking performance is concerned, it is of course of interest to assess which of the investigated methods are mostly related to the properties of the final baked goods. Corresponding data will be published by our project team in a further article [12].
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Acknowledgements
The project FLOURplus has received funding from the European Union’s Seventh Framework Programme for research, technological development, and demonstration under Grant Agreement No. 606198. The GlutoPeak device was provided to ttz Bremerhaven by Brabender, Germany. The measurements on the Chopin devices were performed by Chopin Technologies, France.
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Huen, J., Börsmann, J., Matullat, I. et al. Wheat flour quality evaluation from the baker’s perspective: comparative assessment of 18 analytical methods. Eur Food Res Technol 244, 535–545 (2018). https://doi.org/10.1007/s00217-017-2974-3
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DOI: https://doi.org/10.1007/s00217-017-2974-3