Skip to the main content

Original scientific paper

https://doi.org/10.15567/mljekarstvo.2021.0201

Chemometric approach to quality characterization of milk-based kombucha beverages

Jasmina Vitas orcid id orcid.org/0000-0002-6761-1880 ; University of Novi Sad, Faculty of Technology Novi Sad, Bulevar cara Lazara 1, 21000 Novi Sad, Serbia
Milica Karadžić Banjac ; University of Novi Sad, Faculty of Technology Novi Sad, Bulevar cara Lazara 1, 21000 Novi Sad, Serbia
Strahinja Kovačević ; University of Novi Sad, Faculty of Technology Novi Sad, Bulevar cara Lazara 1, 21000 Novi Sad, Serbia
Stefan Vukmanović orcid id orcid.org/0000-0002-0373-294X ; University of Novi Sad, Faculty of Technology Novi Sad, Bulevar cara Lazara 1, 21000 Novi Sad, Serbia
Lidija Jevrić ; University of Novi Sad, Faculty of Technology Novi Sad, Bulevar cara Lazara 1, 21000 Novi Sad, Serbia
Radomir Malbaša ; University of Novi Sad, Faculty of Technology Novi Sad, Bulevar cara Lazara 1, 21000 Novi Sad, Serbia
Sanja Podunavac-Kuzmanović ; University of Novi Sad, Faculty of Technology Novi Sad, Bulevar cara Lazara 1, 21000 Novi Sad, Serbia


Full text: english pdf 2.515 Kb

page 83-94

downloads: 238

cite

Full text: croatian pdf 2.515 Kb

page 83-94

downloads: 146

cite

Download JATS file


Abstract

Milk-based kombucha beverages were obtained conducting kombucha lead fermentation of milk. In order to discriminate the analysed samples and to detect similarities or dissimilarities among them in the space of experimentally determined variables, hierarchical cluster analysis (HCA) and principal component analysis (PCA) were applied. Linear discriminant analysis (LDA) was conducted on the raw data set in order to find a rule for allocating a new sample of unknown origin to the correct group of samples. In the space of the variables analysed by HCA, the dominant discriminating factor for the studied samples of kombucha beverages is the milk fat (MF) content, followed by total unsaturated fatty acids content (TUFA), monounsaturated fatty acids content (MUFA) and polyunsaturated fatty acids content (PUFA). The samples with 0.8 and 1.6% milk fat belong to the same cluster in the space of the analysed variables due to similarities in their AADPPH. It was determined by LDA that there was the biggest difference in quality between the groups of products with winter savoury and stinging nettle, while the highest similarity is between groups of products with wild thyme and peppermint regarding their pH values and antioxidant activity expressed as AADPPH.

Keywords

kombucha; milk-based products; antioxidant activity; chemometric analysis

Hrčak ID:

254086

URI

https://hrcak.srce.hr/254086

Publication date:

19.3.2021.

Article data in other languages: croatian

Visits: 1.499 *




Introduction

Kombucha is a symbiotic association of bacteria and yeasts. Traditionally, it is well known by its capability to ferment a simple substrate, black or green tea sweetened with sucrose, into non-alcoholic, slightly carbonated refreshing beverage (Kapp and Sumner, 2019). The main characteristic of the traditional kombucha beverage is the possibility of production in a home environment. Also, kombucha products are consumed worldwide (Jayabalan et al., 2016). Beside traditional substrate, kombucha successfully ferments sweetened herbal extracts, coca cola, beer, milk etc. (Jayabalan et al., 2014). Kombucha beverage is a product of natural origin with numerous potential health benefits (Jayabalan et al., 2014) that are related to the presence of vitamins, organic acids, polyphenols, and other components produced during fermentation (Jayabalan et al., 2015). Diverse chemical composition was the reason that kombucha was chosen to be used in the production of milk-based products (Malbaša et al., 2014;Sarkaya et al., 2020;Vitas et al., 2013a).

Milk-based kombucha beverages are obtained after milk inoculation with different kombucha starters and fermentation up to pH 4.50. It could be traditional kombucha inoculums or, for example, inoculums obtained by fermentation on wild thyme, stinging nettle, peppermint or winter savory water extracts sweetened with sucrose (Jayabalan et al., 2014;Malbaša et al., 2014,2009;Vitas et al., 2018,2013a). The main chemical composition and the antioxidant potential of kombucha milk-based beverages obtained using alternative starters was established (Brezo et al., 2011;Kravić et al., 2011;Lončar et al., 2013;Malbaša et al., 2014,2011b;Vitas et al., 2018,2016,2013a,2013b,2011). Latest research suggests that kombucha milk products contain ACE-inhibitory peptides (Elkhtab et al., 2017), and the ACE inhibitory activity of this type of products was determined byHrnjez et al. (2014). Also,Xia et al. (2019) concluded that kombucha enhanced in a significant amount the health-promoting effects of soymilk.

The novelty of this paper is related to the application of modern statistical and mathematical methods to quality evaluation of milk-based kombucha products. Statistical tools used pH value, milk fat and fatty acids content, as well as determined in vitro antioxidant capacity.

Various kombucha products possess antioxidant activity and it is one of the main characteristics which affect the physiological benefits of kombucha beverage. Antioxidant capacity of different kombucha beverages is the consequence of number of ingredients and metabolites such as tea polyphenols, vitamin C, B group vitamins, unsaturated fatty acids and some enzymes (Jayabalan et al., 2008;Vitas et al., 2013a).

Toward additionally clarification of the data which describe kombucha beverages obtained by cultivating milk with kombucha inoculum obtained by fermentation on four different extracts chemometric analysis was carried out.

A method for dividing a group of objects into classes so that similar objects are in the same class (cluster) is known as hierarchical cluster analysis (HCA) (Miller and Miller, 2010). This type of analysis searches for objects which are close together in the variable space. The cluster analysis result is displayed as a tree diagram called a dendrogram, where the horizontal axis represents the distance or dissimilarity between the clusters.

Principal component analysis (PCA) is the mostly used chemometric tool applied to reduce the amount of data and/or obtain orthogonal variables, especially when collinearity occurs (González-Díaz et al., 2007a,2007b). It is suitable for big data sets giving the information regarding data that behave in a similar way. The result of PCA analysis is presented by scores and loadings plots. The new coordinates of the projected objects are scores and loadings reflect the direction with respect to the original variables. The results of PCA analysis could be used as input data for other multivariate techniques instead of original variables (Ciosek and Wróblewski, 2006).

Linear discriminant analysis (LDA), as a supervised pattern recognition method (Miller and Miller, 2010), uses a basically different mathematical approach for sample discrimination than HCA and PCA. Its purpose in this study was to find linear relationships that will be able to define the linear discriminant function (LDF), which linearly combines original variables (Miller and Miller, 2010). The boundary is estimated such that the variance between the groups is maximized and the variance within the individual groups is minimized (Otto, 2017).

Chemometric analysis covered HCA and PCA used to detect similarities or dissimilarities among analysed samples, and LDA was applied toward finding a rule for assigning a new sample of unknown origin to the correct group.

The chemometric approach for characterization and selection is used for textural characteristics of milk-based kombucha products (Malbaša et al., 2015) while it was not used for estimation of quality based on chemical characteristics and antioxidant potential.

The objective of this article is chemometric considerations of milk-based kombucha products with herbal extracts of winter savoury, peppermint, stinging nettle and wild thyme obtained by kombucha fermentation on milk with 2.8, 1.6 and 0.8% milk fat at 37, 40 and 43 °C. Mathematical calculations with obtained experimental results determined the discriminating factor for the classification of the samples based on their quality.

Materials and methods

Production of kombucha milk-based beverages

Samples were obtained according to the procedure described byMalbaša et al. (2014) andVitas et al. (2013a,2018). Briefly, milk with 0.8, 1.6 and 2.8% milk fat was inoculated with kombucha starter obtained by kombucha cultivation on winter savoury, peppermint, stinging nettle and wild thyme water extract with dissolved sucrose. Fermentation of milk was conducted at 37, 40 and 43 °C until medium reached pH 4.50 in accordance to the references mentioned above or no longer than 17h. Samples were marked depending on the used initial substrate (winter savoury water extract - WS, peppermint water extract - P, stinging nettle water extract - SN and wild thyme water extract - WT), applied process temperature and milk fat content of used milk.

Methods of analysis

pH values were determined by a pH-meter (PT-70, Boeco, Germany).

Milk fat content (MF, %) was measured by the Gerber method (IDF 105:1981) (Carić et al., 2000).

Monounsaturated fatty acids (MUFA, %) and polyunsaturated fatty acids (PUFA, %) content was determined by the gas chromatography-mass spectrometry (GC-MS) method (Vitas et al., 2018). The used method covers the extraction of fat, preparation of fatty acids methyl esters and the GC-MS analysis of these esters. Hewlett-Packard (HP) 5890 Series II gas chromatograph coupled an with HP 5971A mass spectrometer detector was applied. Capillary column Supelco fused silica SP-2560 (100 m x 0.25 mm; thickness of stationary liquid phase film 0.20 µm) was applied. Injection volume was 1 µL, injector temperature was set at 230 °C, and the split ratio was 1:40. The carrier gas was helium with 0.58 mL/min constant flow. The temperature program was set at: initial temperature of 100 °C, held for 5 min and increased for 6 °C/min until the final 240 °C was reached (20 min). MS possess an ionic source and works on the principle of electron ionization. The temperature of the quadrupole was 180 °C. Data acquisition was performed in scan mode (in range 50-400 m/z). The multi-Standard solution of 37 fatty acids methyl esters (37 component FAME Mix, 47885-U) from Supelco, Bellefonte, PA, USA was used, as well as the ’Wiley’ commercial database of mass spectra. A modified method of 100% was applied for MUFAs and PUFAs quantification. Total unsaturated fatty acids (TUFA, %) were presented as the sum of MUFA and PUFA. In this paper, values for MUFA, PUFA and TUFA were calculated as the percentage share in milk fat content of the obtained samples, since their presence in the kombucha milk-based beverages comes from milk fat of the milk used for fermentation.

Antioxidant activity to DPPH radical (AADPPH, %) was determined spectrophotometrically according to the (Vitas et al., 2018). Sample preparation covered absolute ethanol (Zorka Pharma Hemija d.o.o., Šabac, Serbia) addition (1:1, v/v) to the sample, after which it was kept for 20 min in the freezer and centrifuged (4000 g) for 30 min at 4 °C. The process was repeated. The obtained supernatant was used for the analysis. The volume of 1 mL of DPPH. radical standard (Sigma-Aldrich® CHEMIE GmbH, Steinheim, Germany) solution in methanol (120 μM) was added to 1.5 mL methanol and 0.5 mL of sample supernatant. The reaction tubes were kept in the dark for 45 min at 25 °C. Absorbance was measured at 515 nm. Antioxidant activity was expressed as inhibition percent (%).

Antioxidant activity to hydroxyl radical (AA.OH, %) was measured spectrophotometrically according to the (Deeseenthum and Pejovic, 2010). The 75 μL of the sample was mixed with 450 μL of sodium phosphate (Merck, Alkaloid, Skoplje, North Macedonia) buffer (0.2 mol/L, pH=7,00), 150 μL of 2-deoxyribose (Alfa Aesar GmbH & Co KG, Karlsruhe, Germany) (10 mmol/L), 150 μL of EDTA disodium salt dihydrate (Lach-Ner, Neratovice, Czech Republic) (10 mmol/L), 150 μL of FeSO4 x 7H2O (Zdravlje, Leskovac, Serbia) (10 mmol/L), 150 μL of H2O2 (Zorka Pharma, Šabac, Serbia) (10 mmol/L), and 525 μL of double-distilled water. Samples were incubated at 37 °C for 4 h after which 750 μL of trichloroacetic (J. T. Baker, Deventer, The Netherlands) (2.8%) acid and 750 μL of thiobarbituric (Alfa Aesar GmbH & Co KG, Karlsruhe, Germany) (0.1%) acid was added. Afterwards, the samples were kept in boiled water for 10 min. Absorbance was measured at 520 nm. 96% ethanol (Reahem, Novi Sad, Serbia) was used as control. Antioxidant activity was expressed as inhibition percent (%).

Chemicals were of analytical and GC purity grade.

All results in this paper were given as mean values of three measurements ± standard deviation determined for each analysed sample.

Chemometric analysis

Chemometric tools HCA, PCA, and LDA were conducted by using Minitab 16.1.1. software. HCA was applied by using Statistica 12.0 and NCSS 2012 software. PCA was applied by using Statistica 12.0 software.

Results and discussion

Results of pH values were obtained in repeated fermentation processes. Results for milk fat content for samples with winter savoury obtained from milk with 1.6% MF at 37, 40 and 43 °C were previously published inVitas et al. (2011). Results for fatty acids content were previously published in several different publications (Brezo et al., 2011;Kravić et al., 2011;Lončar et al., 2013;Malbaša et al., 2014,2011b;Vitas et al., 2018,2016,2013a,2013b,2011), where they were quantified by 100% method, but they were not presented in the form that they are given in this article.

Antioxidant activity of the samples was not presented in this form in previous studies, but as difference between value obtained for product and value obtained for initial milk (Malbaša et al., 2014;Vitas et al., 2018,2013a). Results for samples with winter savoury produced from milk with 1.6% MF at 37, 40 and 43 °C were published inVitas et al. (2016). Antioxidant capacity of samples with stinging nettle obtained using milk with 2.8 and 1.6% MF at 37, 40 and 43 °C was published inVitas et al. (2013b).

Chemometric analysis was carried out on the data (Table 1) which describe kombucha beverages obtained by cultivating milk with kombucha inoculum obtained by fermentation on winter savoury, peppermint, stinging nettle and wild thyme water extracts. Every sample was described by milk fat content, total unsaturated fatty acids content, monounsaturated fatty acids content, polyunsaturated fatty acids content, the antioxidant activity to DPPH and hydroxyl radical, pH value at the start of the fermentation (pHstart), pH value after 8 hours of the fermentation (pH8h) and the final pH value (pHend).

Table 1 The studied samples and their chemical (MF, TUFA, MUFA, PUFA, and pH) and antioxidant properties (AADPPH and AA.OH)
SampleMF (%)TUFA (%)MUFA (%)PUFA (%)AADPPH (%)AA.OH (%)pHstartpH8hpHend
WS-37-2.82.64±0.000.8931±0.00030.7416±0.00030.1515±0.000273.26±2.062.33±0.006.46±0.005.65±0.005.43±0.00
WS-40-2.82.64±0.000.8379±0.00030.7117±0.00030.1259±0.000160.80±1.213.34±0.206.43±0.005.87±0.004.50±0.00
WS-43-2.82.64±0.000.8514±0.00030.7384±0.00030.1133±0.000219.32±0.505.79±0.106.45±0.005.97±0.004.50±0.00
WS-37-1.61.54±0.000.5416±0.00020.4759±0.00010.0658±0.000181.04±2.743.71±0.046.47±0.005.92±0.005.09±0.00
WS-40-1.61.54±0.000.5025±0.00020.4441±0.00020.0585±0.000087.72±3.002.24±0.016.46±0.005.97±0.004.50±0.00
WS-43-1.61.54±0.000.5299±0.00020.4720±0.00020.0581±0.000163.22±2.552.59±0.016.43±0.005.21±0.004.50±0.00
WS-37-0.80.66±0.000.1851±0.00010.1651±0.00000.0200±0.000070.00±2.703.22±0.016.51±0.005.63±0.005.36±0.00
WS-40-0.80.66±0.000.1734±0.00010.1595±0.00000.0139±0.000057.10±1.671.25±0.006.40±0.005.53±0.004.68±0.00
WS-43-0.80.66±0.000.2178±0.00010.1819±0.00000.0360±0.000072.12±3.501.04±0.006.44±0.006.28±0.004.50±0.00
P-37-2.82.64±0.000.9021±0.00040.7487±0.00030.1531±0.000157.08±2.221.76±0.006.22±0.006.12±0.004.50±0.00
P-40-2.82.64±0.000.9082±0.00040.7764±0.00030.1315±0.000135.20±0.363.70±0.006.23±0.006.24±0.004.50±0.00
P-43-2.82.64±0.000.8694±0.00030.7524±0.00020.1170±0.000220.23±0.205.31±0.056.23±0.006.12±0.004.50±0.00
P-37-1.61.54±0.000.5384±0.00020.4657±0.00020.0725±0.000179.91±2.155.06±0.036.24±0.006.20±0.004.71±0.00
P-40-1.61.54±0.000.4736±0.00020.4215±0.00020.0521±0.000082.21±3.503.11±0.036.27±0.006.16±0.004.50±0.00
P-43-1.61.54±0.000.5276±0.00020.4609±0.00020.0667±0.000045.75±1.662.23±0.026.22±0.005.23±0.004.50±0.00
P-37-0.80.66±0.000.2091±0.00010.1827±0.00010.0264±0.000065.55±1.303.66±0.026.25±0.006.12±0.004.50±0.00
P-40-0.80.66±0.000.1749±0.00010.1547±0.00000.0202±0.000060.09±2.101.53±0.006.26±0.005.47±0.004.50±0.00
P-43-0.80.66±0.000.2026±0.00010.1797±0.00010.0229±0.000058.65±1.900.84±0.006.27±0.006.18±0.004.50±0.00
K-37-2.82.64±0.000.8419±0.00040.7186±0.00030.1233±0.000140.00±1.502.43±0.015.90±0.006.03±0.005.07±0.00
SN-40-2.82.64±0.000.9063±0.00050.7447±0.00030.1616±0.000115.73±0.174.28±0.025.87±0.006.01±0.004.50±0.00
SN-43-2.82.64±0.000.9554±0.00040.7806±0.00030.1748±0.000240.23±2.256.29±0.036.02±0.005.98±0.004.50±0.00
SN-37-1.61.54±0.000.5105±0.00020.4602±0.00020.0504±0.000164.12±1.575.50±0.075.95±0.006.00±0.004.60±0.00
SN-40-1.61.54±0.000.5094±0.00020.4480±0.00020.0614±0.000160.40±3.134.72±0.045.95±0.006.01±0.004.50±0.00
SN-43-1.61.54±0.000.5265±0.00020.4580±0.00020.0685±0.000165.06±3.033.01±0.095.93±0.005.37±0.004.50±0.00
SN-37-0.80.66±0.000.2116±0.00020.1760±0.00010.0356±0.000173.78±3.023.55±0.156.04±0.006.04±0.004.62±0.00
SN-40-0.80.66±0.000.1643±0.00000.1457±0.00000.0185±0.000057.94±2.331.60±0.556.04±0.005.43±0.004.50±0.00
SN-43-0.80.66±0.000.1599±0.00000.1460±0.00000.0139±0.000043.27±1.700.68±0.086.05±0.005.90±0.004.50±0.00
WT-37-2.82.64±0.000.9504±0.00030.7904±0.00030.1600±0.000265.17±2.550.78±0.056.27±0.006.31±0.004.50±0.00
WT-40-2.82.64±0.000.9082±0.00040.7519±0.00030.1566±0.000137.33±0.954.95±0.256.27±0.006.28±0.004.50±0.00
WT-43-2.82.64±0.000.8971±0.00040.7281±0.00030.1690±0.000241.36±1.096.41±0.206.29±0.006.25±0.004.50±0.00
WT-37-1.61.54±0.000.5335±0.00020.4709±0.00020.0625±0.000176.97±2.175.61±0.306.30±0.006.30±0.004.64±0.00
WT-40-1.61.54±0.000.5147±0.00030.4528±0.00020.0621±0.000177.44±2.012.76±0.106.30±0.006.24±0.004.50±0.00
WT-43-1.61.54±0.000.5432±0.00000.4759±0.00020.0673±0.000166.21±1.793.39±0.106.30±0.005.91±0.004.50±0.00
WT-37-0.80.66±0.000.1932±0.00000.1692±0.00010.0240±0.000073.33±2.553.75±0.206.33±0.006.17±0.004.57±0.00
WT-40-0.80.66±0.000.1725±0.00000.1533±0.00010.0192±0.000046.57±1.001.56±0.016.27±0.005.65±0.004.50±0.00
WT-43-0.80.66±0.000.1782±0.00000.1592±0.00010.0191±0.000055.13±1.071.08±0.006.24±0.006.13±0.004.50±0.00

In order to discriminate the analyzed samples and to detect similarities or dissimilarities among them in the space of aforementioned experimentally determined variables, HCA and PCA were applied. Prior to analysis, the variables were normalized by min-max normalization method so the values of the variables are scaled in the range 0.01–0.99. LDA was conducted on the raw data set in order to find a rule for allocating a new sample of unknown origin to the correct group of samples.

HCA was applied by using Statistica 12.0 and NCSS 2012 software. The HCA clustering was done on the basis of Ward’s and Single linkage algorithms by calculating Euclidean distances.

The clustering was carried out in two steps. In the first step, all variables were taken into account so the grouping of the samples can be obtained based on chemical composition, antioxidant activity and pH values, whereas the second step included the clustering based only on antioxidant activity and pH values of the samples.

The results of the clustering of the samples on the basis of the whole set of variables are presented inFig. 1a andFig. 1b. InFig. 1a, two well-separated clusters can be observed. According to the results, the samples were very well separated based on milk fat content. The cluster which contain the samples with the highest MF content is significantly separated from the other two. This could mean that these samples can be distinguished from the others not only because of the highest MF content but also on the basis of other determined properties. Considering the results obtained applying the Single linkage algorithm (Fig. 1b) the close placement of the samples which contain 0.8 and 1.6% of MF could be observed as in the case of HCA where Ward’s algorithm was applied. However, in the dendrogram presented inFig. 1b it can be seen that WS-37-2.8 can be considered to be an outlier since it does not belong to any observable cluster. This sample actually had the highest pHend value. According to the measured pHend value (5.43) this sample could not be considered as fermented milk beverage. Kombucha milk-based beverages differ from the other types of kombucha products mainly because of the obtained product’s pH value. Milk fermentation utilizing kombucha ends, similar to yoghurt fermentation, when pH value reaches 4.50, and is significantly shorter compared to the production of traditional kombucha products. These products obtained on black or green tea substrate sweetened with sucrose have lower pH values, usually in the range of 3 to 3.5 (Malbaša et al., 2011a). The main criteria for the end of traditional fermentation, which lasts for 6 to 7 days are, the beverage’s sensory characteristics. However, the approach to kombucha milk fermentation is entirely different. In comparison to traditional kombucha fermentations, the fermentation time required for reaching the pH of 4.50 is considerably shorter when milk is used. Besides that, the antioxidant activity of the obtained kombucha milk-based beverages is significantly different, too. The dendrograms presented inFig. 1c andFig. 1d are obtained when antioxidant activity and pH values of the samples were considered. In this case, the results indicated the significant separation of the samples cultivated on winter savory at 37 °C from the other samples regardless the algorithm used for HCA modelling. These samples are described by the highest pHstart and pHend values, while their antioxidant activity expressed as AADPPH are among the highest. These samples also do not belong to the group of fermented milk products.

Figure 1 Clustering of the samples based on a) Ward’s algorithm and all determined variables; b) Single linkage algorithm and all determined variables; c) Ward’s algorithm and antioxidant activity and pH values; d) Single linkage algorithm and antioxidant activity and pH values
mlj-71-83-f1

In order to analyse the grouping of both variables and samples on only one platform, the double dendrogram was defined on the basis of Ward’s algorithm and Euclidean distances (Fig. 2). The grouping of the samples is almost the same as on dendrogram presented inFig. 1a. Here it can be seen that the samples are very well separated based on MF, followed by TUFA, MUFA and PUFA. Particularly, the group of the samples which contains the highest MF is very well separated from the others (it is placed in the separate cluster). The majority of these samples had the lowest pHend and lowest antioxidant activity expressed as AADPPH. These variables were grouped in the same cluster and could be considered as the main discriminating factor of the samples. The separation of the samples regarding the extracts used and fermentation temperature was not observed. The only overlap between the samples with 0.8 and 1.6% of MF is the sample WS-37-0.8 which was classified together with the samples with 1.6% of MF. The reason for this could be its antioxidant activity and pH values which were similar to the samples with 1.6% of MF.

Figure 2 Double dendrogram of the samples based on Ward’s algorithm and all determined variables
mlj-71-83-f2

In order to gain an overview of distribution of the samples in the space of the analysed variables, PCA was applied by using Statistica 12.0 software. The model resulted in three PCs whose Eigenvalue was greater than 1 covering 79.1% of total variance. The first PC contributes 50.93% to the total variance, while the second one contributes 16.16%. The third PC, which is also described with Eigenvalue higher than 1 contributes 12.01% to the total variance (Table 2 andFig. 3).

Table 2 Eigenvalues and total variances of the PCA model
Factors (PCs)Eigenvalue% Total varianceCumulative EigenvalueCumulative%
14.5850.934.5850.93
21.4516.166.0467.09
31.0812.017.1279.10
40.768.497.8887.59
50.606.648.4894.23
60.465.148.9499.37
70.050.589.0099.95
80.0040.059.00100
9009.00100
Figure 3 Eigenvalues of correlation matrix of the established PCs (Factors)
mlj-71-83-f3

The score and loadings plots of the PCA are presented inFig. 4. The results of PCA are in agreement with the results of the HCA, however they reveal more regarding similarities and dissimilarities among the samples. Going along the Factor 1 (PC1) axis, it can be seen that there is a quite good separation between the samples based on their MF content. Considering the distance between the samples, it can be noticed that the samples with the highest MF content are significantly separated from the negative end of the Factor 1 axis. This inequality between the distances among the samples is probably caused due to certain influence of AA.OH and AADPPH and small influence of pH8h variables on Factor 1 axis. Therefore, generally speaking, the samples which contain 0.8% and 1.6% MF are placed closer on the score plot mainly because of their similarities regarding AA.OH and AADPPH values. The score and loadings plot indicate that the majority of the samples which contain 2.8% MF have the lowest AADPPH and high AA.OH potential. The presented values were different in comparison to traditional black or green tea kombucha beverages. The AA.OH values of traditional kombucha beverages are much higher compared to milk-based ones. The highest AA.OH value of the kombucha milk-based beverages was 6.41% for the WT-43-2.8 (Table 1) while the AA.OH values of traditional kombucha beverages were in a range of approximately 40 to 60% (Malbaša et al., 2011a). The AADPPH of the kombucha milk-based beverages were in a wide range and varied from 15.73 to 87.72% (Table 1). The average AADPPH of the traditional black or green tea kombucha beverages was around 40% (Malbaša et al., 2011a). The forehead mentioned differences in the chemical composition of substrates and starters for the traditional and milk fermentation of kombucha affected AA.OH greatly, while the differences of AADPPH were not much pronounced. The differences in antioxidant activities between kombucha milk-based beverages could be due to the different chemical compositions of the applied kombucha starters besides the different fermentation temperatures and milk fat percent in the substrate. Thymol and carvacrol are the main components of winter savoury and wild thyme. It is typical for the wild thyme that carvacrol content is higher than thymol content (de Oliveira et al., 2011;Zavatti et al., 2011;Fecka and Turek, 2008). The peppermint’s main components are menthol, menthone, and limonene (Akdogan et al., 2004), while formic acid, histamine, serotonin, and acetylcholine are the typical components of stinging nettle (Cummings and Olsen, 2011;Hojnik et al, 2007).

Figure 4 The loadings (a) and score plots (b) of the studied samples as a result of the PCA
mlj-71-83-f4

The distribution of the samples along the Factor 2 axis was mainly caused by pHend and pHstart values, and to a lesser extent by AADPPH values, as it can be seen on the loadings plot. The samples with WS extract and fermentation temperature of 37 °C had the highest pHend and pHstart values and among the highest antioxidant activities (AADPPH). On the other hand, the majority of the samples which contained stinging nettle extracts (SN) were placed at the end which implies low pHstart and pHend values, regardless the MF content and fermentation temperature. However, these samples had low, moderate and high antioxidant activity (AADPPH) and could not be classified as the samples with only high nor only low AADPPH values (AADPPH express moderate influence on samples distribution on the score plot along the Factor 1 axis). The separation of other groups of the samples along the Factor 2 axis was not observed.

The samples were divided into four groups regarding the extract used in their fermentation: SN, WS, P and WT. The analysis was carried out considering the following variables: AADPPH, AA.OH, pHstart, pH8h and pHend. Since the normalization of the variables had no effect on the outcome of LDA (Miller and Miller, 2010), the analysis was done on the raw data. The validation of the established functions was conducted applying the cross-validation (CV) method.

The obtained results are presented inTable 3. One sample was put into specified group when Mahalanobis squared distance of observation to the group centre (mean) is minimum. The confusion matrix shows a success rate of 100% (9 correct hits out of 9), 77.8% (7 correct hits out of 9), 77.8% (7 correct hits out of 9) and 100% (9 correct hits out of 9) for the groups SN, WT, P and WS, respectively. The proportion of the correct hits is 88.9%. When the leave-one-out (LOO) cross-validation is carried out 100% (9 correct hits out of 9), 66.7% (6 correct hits out of 9), 66.7% (6 correct hits out of 9) and 100% (9 correct hits out of 9) for the groups SN, WT, P and WS, respectively. During the LOO-CV, the proportion of the correct hits was 83.3%. This success in allocating an object correctly of 83.3% could be considered satisfactory. The squared distances between the groups indicate that there was the biggest distance between groups WS and SN, while the highest similarity was between groups WT and P. This close placement of WT and P samples is reflected in the fact that false classifications occur only in these groups, as it is shown inTable 2.

Table 3 Linear discriminant analysis of the analysed samples
GroupSNWTPWS
Count9999
Summary of classification (confusion matrix)
True group
Put into GroupSNWTPWS
SN9000
WT0720
P0270
WS0009
Total N9999
N correct9779
Proportion100%77.8%77.8%100%
N Total = 36; N Correct = 32; Proportion Correct = 88.9%
Summary of classification with LOO cross-validation (confusion matrix)
True group
Put into groupSNWTPWS
SN9000
WT0630
P0360
WS0009
Total N9999
N correct9669
Proportion100%66.7%66.7%100%
N Total = 36; N Correct = 30; Proportion Correct = 83.3%
Squared distance between groups
SNWTPWS
SN069.96553.016159.250
WT69.96501.40621.149
P53.0161.406030.235
WS159.25021.14930.2350

The established linear discriminant functions used for linear discriminant scores calculations for the studied groups of samples are the following:

SN = –13144 – 4 · AADPPH – 12 · AA.OH + 4304 · pHstart + 86 · pH8h + 73 · pHend (1)

WT = –14514 – 4 · AADPPH – 13 · AA.OH + 4527 · pHstart + 90 · pH8h + 70 · pHend (2)

P = –14330 – 4 · AADPPH – 13 · AA.OH + 4499 · pHstart + 88 · pH8h + 70 · pHend (3)

WS = –15241 – 4 · AADPPH – 13 · AA.OH + 4643 · pHstart + 86 · pH8h + 74 · pHend (4)

The obtained results of LDA indicate that there was a significant separation between the studied kombucha products on the basis of the exact mathematical equations (1-4) which correlate antioxidant activity and pH values with a product type. Therefore, there was the function which reflects the difference between groups as much as possible. On the basis of the established equations 1-4 (linear discriminant function for groups), the highest probability (100%) of the correct classification is evident in the group of kombucha beverages with stinging nettle (SN) and wild thyme tea extracts (WT).

In order to explain the differences between the samples when pH value was taken into account, the pHend value was observed, as the most important. If this parameter’s value was 4.50, it indicated that the analysed sample was a fermented milk product. Therefore, samples WS-37-2.8, WS-37-1.6, WS-37-0.8, WS-40-0.8, P-37-1.6, K-37-2.8, SN-37-1.6, SN-37-0.8, WT-37-1.6, and WT-37- 0.8 were not the products that could be consumed, and that was the main difference in comparison to other samples. Based on these results, it could be seen that the main influencing factor to the obtaining of the kombucha fermented milk product was the fermentation temperature of 37 °C, as the least suitable one. Fermentation was stopped after 17h of duration, the longest, for all samples that did not reach the pH value of 4.50. Samples P-37-2.8 and P-37-0.8 reached a pH value of 4.50 after 17 h. The production process of samples WS-43-1.6 and P-43-1.6 was the shortest and lasted for about 10 h.

Higher values of the antioxidant activity to DPPH and hydroxyl radical indicate the higher quality of the certain sample, and this fact was chosen in order to explain differences among samples regarding their antioxidant capacity. These values are not given in regulation, and based on the results given inTable 1, it can be established that the best antioxidant quality characteristics possess samples WS-40-1.6 (AADPPH was 87.72%) and WT-43-2.8 (AA.OH was 6.41%). These results suggest that higher process temperatures and milk fat content lead to a better quality of kombucha fermented products.Hrnjez et al. (2014) determined the radical scavenging ability of DPPH and ABTS radical of kombucha milk-based beverages with black tea during the 14 days long storage. The AADPPH (%) was the highest after the production and amounted to around 18%, while the ABTS (%) was around 41%. Therefore, the kombucha fermented milk products with different herbs (peppermint, wild thyme, stinging nettle, and winter savory) possess stronger antioxidant capacity than the kombucha fermented milk products with black tea. The exception was sample SN-40-2.8, whose AADPPH was 15.73%.

Conclusions

The general conclusion was that the chemometric analysis was successfully applied in the classification of the kombucha products, based on their quality characteristics. The purpose of the applied chemometric tools was the comprehensive approach to the selection of products among different groups. This is important for the production process of beverages that have similar characteristics; there is a justification for the production of the group with the shorter duration of the fermentation.

The presented results of chemometric analysis indicate that in the space of the variables analysed by HCA, the dominant discriminating factor for the studied samples of kombucha beverages is MF% content, followed by total unsaturated fatty acids content (TUFA, %), monounsaturated fatty acids content (MUFA, %) and polyunsaturated fatty acids content (PUFA, %). It was determined that the samples with 0.8% MF and 1.6% MF belong to the same cluster in the space of the analysed variables due to similarities in their antioxidant activity (AADPPH). The samples fermented at 37 °C with winter savoury extracts are significantly separated from the others based on their highest pHstart and pHend values, while their antioxidant activity expressed as AADPPH is among the highest, but these samples are not fermented milk products and cannot be consumed. The differences in quality of the studied samples are more pronounced regarding their chemical composition than antioxidant activity.

LDA successfully found functions that characterizes the analysed samples and successfully allocate new samples of unknown group to the correct group of samples. Also, by LDA was determined that there is the biggest difference in quality between the groups WS and SN, while the highest similarity is between groups WT and P regarding their pH values and antioxidant activity expressed as AADPPH.

Acknowledgements

Authors want to thank to the Ministry of Education, Science and Technological Development of the Republic of Serbia (Grant 451-03-68/2020-14/200134) and Provincial Secretariat for Higher Education and Scientific Research (Project name: Kombucha beverages production using alternative substrates from the territory of the Autonomous Province of Vojvodina; Project No. 142-451-2400/2019-03) for financing the investigations presented in this article.

References

1 

Akdogan M, Ozguner M, Kocak A, Oncu M, Cicek E. Effects of peppermint teas on plasma testosterone, follicle-stimulating hormone, and luteinizing hormone levels and testicular tissue in rats. Urology. 2004;64:394–8. https://doi.org/10.1016/j.urology.2004.03.046 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/15302514

2 

Brezo, T.Ž., Kravić, S.Ž., Suturović, Z.J., Karišik-Đurović, A.D., Vitas, J.S., Malbaša, R. V, Milanović, S.D. (2011): Influence of kombucha inoculum on the fatty acidcomposition of fermented milk products. Food Industry - Milk and dairy products 22, 21-24.

3 

Carić, M., Milanović, S., Vucelja, D. (2000): Standardne metode analize mleka i mlečnih proizvoda. Prometej, Novi Sad, Serbia.

4 

Ciosek P, Wróblewski W. The analysis of sensor array data with various pattern recognition techniques. Sens Actuators B Chem. 2006;114:85–93. https://doi.org/10.1016/j.snb.2005.04.008

5 

Cummings AJ, Olsen M. Mechanism of action of stinging nettles. Wilderness Environ Med. 2011;22:136–9. https://doi.org/10.1016/j.wem.2011.01.001 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/21396858

6 

Deeseenthum S, Pejovic J. Bacterial inhibition and antioxidant activity of kefir produced from Thai Jasmine rice milk. Biotechnology (Faisalabad). 2010;9:332–7. https://doi.org/10.3923/biotech.2010.332.337

7 

de Oliveira T.L.C, de Araújo Soares R.; Mendes Ramos E., das Graças Cardoso, M., Alves, E., Hilsdorf Piccoli, R. Antimicrobial activity of Satureja montana L. essential oil against Clostridium perfringens type A inoculated in mortadella-type sausages formulated with different levels of sodium nitrite. Int J Food Microbiol. 2011;144:546–55. https://doi.org/10.1016/j.ijfoodmicro.2010.11.022 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/21131083

8 

Elkhtab E, El-Alfy M, Shenana M, Mohamed A, Yousef AE. New potentially antihypertensive peptides liberated in milk during fermentation with selected lactic acid bacteria and kombucha cultures. J Dairy Sci. 2017;100:9508–20. https://doi.org/10.3168/jds.2017-13150 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/28964516

9 

Fecka I, Turek S. Determination of polyphenolic compounds in commercial herbal drugs and spices from Lamiaceae: thyme, wild thyme and sweet marjoram by chromatographic techniques. Food Chem. 2008;108:1039–53. https://doi.org/10.1016/j.foodchem.2007.11.035 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/26065769

10 

González-Díaz H, Saiz-Urra L, Molina R, Santana L, Uriarte E. A model for the recognition of protein kinases based on the entropy of 3D van der waals interactions. J Proteome Res. 2007a;6:904–8. https://doi.org/10.1021/pr060493s PubMed: http://www.ncbi.nlm.nih.gov/pubmed/17269749

11 

González-Díaz H, Saíz‐Urra L, Molina R, González‐Díaz Y, Sánchez‐González A. Computational chemistry approach to protein kinase recognition using 3D Stochastic van der Waals spectral moments. J Comput Chem. 2007b;28:1042–8.https://doi.org/https://doi.org/10.1002/jcc.20649 https://doi.org/10.1002/jcc.20649 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/17269125

12 

Hojnik M, Škerget M, Knez Ž. Isolation of chlorophylls from stinging nettle (Urtica dioica L.). Separ Purif Tech. 2007;57:37–46. https://doi.org/10.1016/j.seppur.2007.02.018

13 

Hrnjez D, Vaštag Ž, Milanović S, Vukić V, Iličić M, Popović Lj, et al. The biological activity of fermented dairy products obtained by kombucha and conventional starter cultures during storage. J Funct Foods. 2014;10:336–45. https://doi.org/10.1016/j.jff.2014.06.016

14 

Jayabalan R, Malbaša RV, Sathishkumar M. (2015) Kombucha Tea: Metabolites. In: Merillon JM., Ramawat K. (eds) Fungal Metabolites. Reference Series in Phytochemistry. Springer, Cham. https://doi.org/10.1007/978-3-319-19456-1_12-1 https://doi.org/10.1007/978-3-319-19456-1_12-1

15 

Jayabalan, Malbaša, R. V., Sathishkumar, M. (2016). Kombucha. Reference Module in Food Science, 1-8, Elsevier. https://doi.org/10.1016/B978-0-08-100596-5.03032-8 https://doi.org/10.1016/B978-0-08-100596-5.03032-8

16 

Jayabalan R, Malbaša RV, Lončar ES, Vitas JS, Sathishkumar M. A review on kombucha tea-microbiology, composition, fermentation, beneficial effects, toxicity, and tea fungus. Compr Rev Food Sci Food Saf. 2014;13:538–50. https://doi.org/10.1111/1541-4337.12073 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/33412713

17 

Jayabalan R, Subathradevi P, Marimuthu S, Sathishkumar M, Swaminathan K. Changes in free radical scavenging activity of Kombucha during fermentation. Food Chem. 2008;109:227–34. https://doi.org/10.1016/j.foodchem.2007.12.037 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/26054285

18 

Kapp JM, Sumner W. Kombucha: a systematic review of the empirical evidence of human health benefit. Ann Epidemiol. 2019;30:66–70. https://doi.org/10.1016/j.annepidem.2018.11.001 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/30527803

19 

Kravić S, Suturović Z, Brezo T, Ana K-Đ, Vitas J, Malbaša R, et al. (2011): Characterisation of fatty acid composition in milk-based kombucha products, in: 2nd CEFSER Workshop "Persistent Organic Pollutants in Food and Environment", 26th Symposium on Recent Developments in Dairy Technology, BIOXEN Seminar "Novel Approaches for Environmental Protection". University of Novi Sad, Faculty of Technology, Novi Sad, Serbia, pp. 268-272.

20 

Lončar E, Vitas J, Kravić S, Milanović S, Malbaša R. (2013): GC-MS determination of fatty acids in kombucha fermented milk products obtained using nontraditional inoculums, in: 15th DKMT Euroregion Conference on Environment and Health with Satellite Event LACREMED Conference "Sustainable Agricultural Production: Restoration of Agricultural Soil Quality by Remediation". University of Novi Sad, Faculty of Technology, Novi Sad, Serbia, pp. 151-155.

21 

Malbaša R, Lončar E, Vitas J, Čanadanović-Brunet J. Influence of starter cultures on the antioxidant activity of kombucha beverage. Food Chem. 2011a;127:1727–31. https://doi.org/10.1016/j.foodchem.2011.02.048

22 

Malbaša R, Jevrić L, Lončar E, Vitas J, Podunavac-Kuzmanović S, Milanović S, et al. Chemometric approach to texture profile analysis of kombucha fermented milk products. J Food Sci Technol. 2015;52:5968–74. https://doi.org/10.1007/s13197-014-1648-4 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/26345015

23 

Malbaša RV, Milanović SD, Lončar ES, Djurić MS, Carić MD, Iličić MD, et al. Milk-based beverages obtained by Kombucha application. Food Chem. 2009;112:178. https://doi.org/10.1016/j.foodchem.2008.05.055

24 

Malbaša RV, Vitas JS, Lončar ES, Kravić SŽ. Influence of fermentation temperature on the content of fatty acids in low energy milk-based kombucha products. Acta Period Technol. 2011b;42:81–90. https://doi.org/10.2298/APT1142081M

25 

Malbaša R, Vitas J, Lončar E, Grahovac J, Milanović S. Optimisation of the antioxidant activity of kombucha fermented milk products. Czech J Food Sci. 2014;32:477–84. https://doi.org/10.17221/447/2013-CJFS

26 

Miller JN, Miller JC. (2010): Statistics and Chemometrics for Analytical Chemistry, 6th edition. ed. Pearson, Harlow, UK.

27 

Otto M. (2017): Chemometrics: Statistics and Computer Application in Analytical Chemistry, 3rd edition. ed. Wiley-VCH Verlag GmbH & Co., Weinheim, Germany.

28 

Sarkaya P, Akan E, Kinik O. Use of kombucha culture in the production of fermented dairy beverages. Lebensm Wiss Technol. 2020; (article in press) https://doi.org/10.1016/j.lwt.2020.110326

29 

Vitas J, Malbaša R, Jokić A, Lončar E, Milanović S. ANN and RSM modelling of antioxidant characteristics of kombucha fermented milk beverages with peppermint. Mljekarstvo. 2018;68:116–25. https://doi.org/10.15567/mljekarstvo.2018.0205

30 

Vitas J, Malbaša R, Lončar E, Kravić S. (2016): Influence of unsaturated fatty acids content and fermentation temperature on the antioxidant activity of kombucha milk beverages with winter savory, in: 18th DKMT Euroregional Conference on Environment and Health. University of Novi Sad, Faculty of Technology, Novi Sad, Serbia, pp. 78-84.

31 

Vitas JS, Malbaša RV, Grahovac JA, Lončar ES. The antioxidant activity of kombucha fermented milk product with stinging nettle and winter savory. Chem Ind Chem Eng Q. 2013a;19:129–39. https://doi.org/10.2298/CICEQ120205048V

32 

Vitas, J.S., Malbaša, R. V., Lončar, E.S., Milanović, S.D., Kravić, S.Ž., Suturović, I.Z. (2013b): Antioksidativna aktivnost i sadržaj mononezasićenih kiselina u fermentisanim mlečnim proizvodima dobijenim pomoću kombuhe. Food Industry - Milk and dairy products 24, 19-22.

33 

Vitas, J.S., Malbaša, R. V, Lončar, E.S., Kravić, S.Ž., Milanović, S.D. (2011): Masne kiseline u mlečnim proizvodima dobijenim pomoću kombuhe kultivisane na rtanjskom čaju. Food Industry - Milk and dairy products 22, 25–28.

34 

Xia X, Dai Y, Wu H, Liu X, Wang Y, Yin L, et al. Kombucha fermentation enhances the health-promoting properties of soymilk beverage. J Funct Foods. 2019;62:103549. https://doi.org/10.1016/j.jff.2019.103549

35 

Zavatti M, Zanoli P, Benelli A, Rivasi M, Baraldi C, Baraldi M. Experimental study on Satureja montana as a treatment for premature ejaculation. J Ethnopharmacol. 2011;133:629–33. https://doi.org/10.1016/j.jep.2010.10.058 PubMed: http://www.ncbi.nlm.nih.gov/pubmed/21040774


This display is generated from NISO JATS XML with jats-html.xsl. The XSLT engine is libxslt.