Diffraction Scanning Calorimetric Analysis of Fully Hydrogenated Soybean Oil and Soybean Oil Blends |
Ibtesam Ibrahim Ahmed1*, Manal Abdel Rahman Sorour1, Mohamed Said Abbas2, Amira Shawky Soliman2 |
1Department of Food Engineering and Packaging, Food Technology Institute, ARC, Egypt. 2Department of Natural Resource, Faculty of African Postgraduate Studies, Cairo University, Egypt. |
Abstract
In this study, a binary combination consisting of native soybean oil (SO) and fully hydrogenated soybean oil (FH) in varying ratios of 40:60 (F4S6) and 45:55 (F45S55) was compared with partly hydrogenated shortening (PH) as the control. Thermophysical characteristics of F4S6, F45S55, and control were investigated by the application of differential scanning calorimetry (DSC). With a 60m 8×0.32mm×0.25um DB-23 capillary column and a flame ionisation detector (FID), fatty acid and methyl esters of fat were measured using gas-liquid chromatography (HP 6890 GC capillary) The shelf life of all samples was determined. The results observed that melting occurs at approximately 27, 39, and 48 for soybean oil as a control sample, F4S6 and F45S55, respectively. So, the addition of fully hydrogenated soybeans increases the melting point of oil. For the melting enthalpy ΔHm, the lowest was for PH, and the highest ΔHm was for F4S6. The GC data represented the highest value of C18: I found in FH followed by PH, F45S55, and then F4S6 85.07, 23.64, 14.13 and 13.35 %w, respectively. The data illustrated that F4S6 and F45S55 had no trans fatty acid (TFA) of oleic acid (C18:1T) compared with the control (PH), which had around 16.976. However, F4S6 and F45S55 had very small amounts of trans fatty acid of linoleic acid (C18:2T) compared with control (PH), which recorded 0.09, 0.09, 0.01 and 0.49 %w, respectively. In general, the blended fatty from soybean oil and fully hydrogenated soybean oil (F4S6 and F45S55) improved sample sensory properties compared with the control.
Keywords: DSC, Soybean oil, Fully hydrogenated oil, Thermal properties
Introduction
Glycine max L. Merrial, or soybean, is the most produced crop in the world and accounts for around 56% of all oilseed goods. Antioxidants, vitamins, lecithin, and nutraceuticals are among the high-value and secondary co-products that are thought to originate mostly from soybeans. Low in saturated fat and free of trans fat, soybean oil is a suitable source. On the other hand, we must combine completely hydrogenated (FHSBO) with soybean oil (SO) in order to raise its melting point [1]. It is also believed that soybean oil is trans-free [2]. Therefore, instead of using partial hydrogenation to make shortening, margarine, and confections, a binary combination of FHSBO and SO is employed [3, 4]. One of the few non-fish forms of omega-3 polyunsaturated fatty acids, which offer a number of physiological advantages, including cardioprotective properties, is soybean oil. The American Journal of Clinical Nutrition [5] states that, in contrast, fish oil is the main source of omega-3s in the American diet. A new piece of research released by the American Heart Association suggests that omega-6 fatty acids, which are naturally present in soybean oil, may also lower the risk of heart disease itself. Numerous phytosterols found in soybean oil, such as stigmasterol, campesterol, and ß-sitosterol, have been demonstrated to lower LDL cholesterol and blood cholesterol by at least 5 to 10%. A common practice is partial hydrogenation. However, some of the cis double bonds isomerize during the partial hydrogenation of vegetable oils, which results in around 50% of TFA [6]. Compared to cis-fatty acids, trans-fatty acids are more stable and have higher melting points. It is challenging to pack the molecules of cis-fatty acids together due to their kink form [5]. In contrast, TFA has a linear form that facilitates the packing of its molecules. Numerous research investigations on nutrition have proposed a connection between TFA levels and coronary heart disease [7]. TFA has been linked to increased levels of high-density cholesterol (HDL) and low-density lipoprotein (LDL) [1-8].
According to studies, cutting back on our daily calorie intake by 5% of saturated fat will lower our risk of cardiovascular disease by 22–37%. In [9].
Differential Scanning Calorimetry (DSC) technique is used in this study to obtain the melting points associated with the polymorphic transformations formed at different cooling rates and the thermal characteristics of enthalpy of fats and oils [10]. Additionally, the way in which materials exhibiting thermal transitions like melting and crystallisation are affected by differential heat flow with temperature [11, 12].
Through the use of differential scanning calorimetry (DSC), the thermal characteristics of many samples (PH as a control, F4S6, and F45S55) were investigated. The movement of heat modifications to the sample is linked to the development or absorption of heat, which is then noted as a peak [13]. Thermal enthalpy must be taken in or released during the two basic physical processes—melting and crystallisation—that are used to describe the thermal behaviour of samples combined with fat. DSC may be used to ascertain the physical characteristics of various samples that have been combined with fat. DSC was used to establish the thermal curves for partly hydrogenated soybean oil (PH) and fat blends including both fully hydrogenated and partially hydrogenated soybean oil (F45S55, F4S6).
Finding the thermal properties of a low-trans and low-saturated-fatty acid healthy shortening made from a blended blend of fully hydrogenated soybean oil and soybean oil is the goal of this study in order to assist manufacturers in finding a substitute for partially hydrogenated oils, which are a major source of harmful trans fatty acids.
Materials and Methods
Safola Oil Company, Suez Governorate, Egypt, provided the soybean oil and partly hydrogenated soybean oil, while General Mills Company, Canada, provided the completely hydrogenated soybean oil.
Thermal characteristics determination by DSC
Differential Scanning Calorimetry (DSC) (TA instrument DSC Q 100, Newcastle, DE, USA) conducted at Dalhousie University, Canada, 1913. The DSC technique was used in this study to determine the thermal characteristics of enthalpy and the melting points associated with the polymorphic transformations formed at different cooling rates. Three cycles were conducted for all samples compared with the control one. Figures 1 and 2 revealed all experiments (3 cycles) for F4S6, F45S55, and control, respectively. Using three temperature cycles, the DSC was utilised to compare the sample's rate of heat transfer to that of the reference, an empty pan. In order to eliminate any crystallised history, samples were heated to 70°C in the first cycle at a rate of 25°C/min. They were then cooled to 20°C at a rate of 10°C/min, and they were maintained at this temperature for one hour. The samples were heated once again in the second cycle at a rate of 25°C/min to achieve 70°C/min. They were then cooled to 10°C at a rate of 10°C/min and stored for about an hour. The samples were eventually heated to 70°C by the rete 25°C/min in the third cycle. After that, they were cooled by 10°C/min to 1°C and were maintained for almost an hour.
Analysis of fatty acids using Gas Liquid chromatography
Preparation of fatty acids methyl ester
The fast process described in [14] would be used to create fatty acid methyl esters from total lipids. Comparatively, before saponification occurs, fatty acid methyl esters undergo esterification using methanolic potassium hydroxide as a transitional step. A 5-ml screwtop test tube containing around 0.1 g of the oil was filled with 2 ml of heptan, and the tube was then shaken. A 0.2 ml (2N) methanolic potassium hydroxide solution was added to the cap and allowed to stratify until the top solution turned clear. The upper layer containing the methyl ester was then decanted. It is OK to inject the heptane solution into the gas chromatography.
Separation and identification of fatty acid methyl esters by Gas Liquid Chromatography (GLC)
A GLC (HP 6890 GC capillary) fitted with a flame ionisation detector (FID) and a 60-m 8×0.32mm×0.25um DB-23 capillary column was used to measure the methyl esters of fat and fatty acids. At 2300C and 2500C, respectively, the injector and detector temperatures were set. A carrier gas of 40 millilitres per minute (ml/min) of hydrogen was used, and the temperature programming ranged from 150 to 170 0C at 100 c/min, followed by 1700 to 1920 °C at 50 c/min for five minutes, and finally 1920 to 2200 °C for ten minutes. Through comparison with established standards, individual methyl esters were identified [14]. In 2000, IUPAC.
Shelf-life determination
The Rancimat (679 Metroham) apparatus was used to measure the stability of each sample (5 g of each sample at 120 °C and an air flow rate of 20 L/h) and calculate the shelf life of the novel shortening mix with varied concentrations of FHSO: SO (40:60 and 45:55 by weight).
Statistical analysis
Software [15] (CoStat, 2005) would be used to statistically analyse the results obtained. First, an analysis of variance (ANOVA) was performed on each multiple comparison. The least significant difference (LSD), as selected by Steel and Torrie [16] and Gomez [17], would be used to compare means in order to identify any significant differences between different treatments at P ≤ 0.01 and 0.01.
Results and Discussion
Thermal analysis of samples by DSC
Thermal properties of different samples (PH as control, F4S6, and F45S55) were examined using differential scanning calorimetry (DSC). A peak is created by variations in the sample that are linked to the development or absorption of heat and result in a change in the distinct heat flow [13]. As shown in Figures 1a-1c and Table 1, the thermal curves were established using DSC as the control for partly hydrogenated soybean oil (PH) and fat blends of fully hydrogenated soybean oil (FH) and soybean oil (SO) (F45S55, F4S6). The thermal behaviour of oil samples has been characterised by the two main physical phenomena, melting and crystallisation, which both require the intake or release of thermal enthalpy. As shown in Figures 2a-2c and Table 1, thermal curves were calculated using DSC for samples of F45S55, F4S6, and soybean oil (SO). When a sample is heated or cooled below its phase transition temperature, it stays isothermal for a brief period of time before being heated or cooled again to its starting temperature. The results observed that melting occurs at approximately 27, 39, and 48 for soybean oil as control samples, F4S6 and F45S55, respectively. The addition of fully hydrogenated soybean increases the melting point of oil due to the fact that crystallization was influenced only by the chemical composition of the sample. Also, exothermic peaks are observed in all samples, indicating recrystallization.
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b) |
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c) |
Figure 1. Represented the three temperature cycles conducted on DSC a) for control, b) for F45S55 and c) for F4S6 |
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a) |
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b) |
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c) |
Figure 2. Differential scanning Calorimetric crystallization curves: a) for F4S6, b) for F45S55 and c) for control |
The following five DSC parameters were determined for the primary thermal curve in all fat and oil samples: onset temperature (To), offset temperature (Tf), temperature range (Tr) (the difference between to and Tf), peak temperature, and melting enthalpy (ΔHm) and melting temperature (Tm): This is the first peak temperature; the peak is reached at this point when the measured data's curve starts to diverge from the baseline. The temperature at its highest point is TM. This temperature is the greatest value of the deviation between the interpolated baseline and the observed value curve. The temperature at which the measured value curve returns to the baseline is the final peak, or Tf. At this point, the peak is finished.
A summary of the DSC parameters is provided in Table 1. According to the data, sample F4S6 had the greatest peak melting temperature (39 °C), and sample SO had the lowest peak melting temperature (27°C). The peak melting temperatures varied from 27°C to 39°C. Variations were observed in the melting enthalpies (ΔHm). According to the statistics, F45S55 had the lowest ΔHm (35.73 J/g), followed by F4S6 (45.75 J/g). The control group had a much higher ΔHm (113.9 J/g), which might be related to the medium chain's high content of saturated fatty acids.
At a certain temperature, the fraction of solid fat that remains is typically equal to the partial area beneath the melting peak, or endothermic event. According to [18-20], the amount of fat that crystallises in liquid oil is determined using the DSC method. The findings were in line with Veerle's [21] findings, according to which DSC trans-free samples exhibited a two-step exothermic crystallisation that was produced by DSC at 10°C and was thought to be an α-mediated and β' polymorphism.
Table 1. Thermal profile (To, Tp, Tf, Tr, ∆Hm) obtained from DSC |
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Samples |
To, °C |
Tm, °C |
Tf, °C |
Tr, °C |
ΔHm (J/g) |
PH |
20 |
27 |
32 |
5 |
113.9 |
F4S6 |
28 |
39 |
44 |
16 |
45.75 |
F45S55 |
25 |
48 |
46 |
21 |
35.73 |
To: Onset temperature; Tf- Offset temperature; Tm- Peak temperature; Tr- Range of temperature; ΔHm- Melting enthalpy
Analyses of fatty acids by using Gas Liquid Chromatography
In accordance with the IUPAC technique [14], fatty acid methyl esters were made from total lipids using a fast approach. Using gas-liquid chromatography, fatty acid methyl esters of fat were measured. Through comparison with the established standard library (IUPAC), individual methyl esters were found. The constituents of the samples were examined. Table 2 displays the main constituents of the samples. Gas-liquid chromatography was used to quantify the fatty acid methyl esters of fully hydrogenated soybean oil (FH), as well as the fatty blend of completely hydrogenated soybean oil and soybean oil with varying ratios (40:60 and 45:55) (F4S6 and F45S55) in comparison with partly hydrogenated soybean oil (PH). A trans-fat is produced when the unsaturated fat undergoes partial hydrogenation, which changes some of the cis-double bonds into trans-double bonds through an isomerization process with the hydrogenation catalyst [22, 23].
Table 2. GC profile of all samples (fatty acid %w) |
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Samples |
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Fatty acids |
F45S55% |
F4S6% |
FH% |
PH% |
C14:0 |
0.072 |
0.000 |
0.087 |
0.287 |
C16:0 |
11.348 |
11.692 |
12.332 |
16.298 |
C16:1 |
0.053 |
0.061 |
0.007 |
0.052 |
C17:0 |
0.206 |
0.202 |
0.332 |
0.135 |
C17:1 |
0.038 |
0.039 |
0.018 |
0.062 |
C18:0 |
40.841 |
37.159 |
0.000 |
28.818 |
C18:1T |
0.000 |
0.000 |
0.074 |
16.976 |
C18:1 |
13.352 |
14.128 |
85.073 |
23.637 |
C18:2T |
0.096 |
0.090 |
0.012 |
0.499 |
C18:2 |
29.114 |
31.208 |
0.207 |
6.782 |
C18:3n6 |
0.000 |
0.173 |
0.000 |
0.205 |
C18:3n3 |
3.911 |
4.257 |
0.156 |
0.449 |
C20:0 |
0.475 |
0.445 |
0.625 |
0.457 |
C20:1 |
0.132 |
0.103 |
0.000 |
0.092 |
C22:0 |
0.363 |
0.349 |
0.383 |
0.338 |
C22:1 |
0.000 |
0.000 |
0.005 |
0.000 |
C24:0 |
0.000 |
0.958 |
0.111 |
0.106 |
Fatty Acids composition of all samples under this study (%w)
Organoleptic properties
Data presented in Table 3 shows the sensory evaluation of the blended shortening F4S6 and F45S55 compared with the control. The data revealed that F4S6 gained the highest panelist score in taste, followed by F45S55, which ended with the control. This may be the return that the more soybean oil is added to the blended mixture of soybean oil and fully hydrogenated soybean oil, the more lipid taste should appear. However, there is no significant difference between all treatments and control in color. It was also clear from the same Table that texture was quite high for F4S6 and the same for F45S55 and control. In general, the blended fatty from soybean oil and fully hydrogenated soybean oil (F4S6 and F45S55) improved sample sensory properties compared with the control.
Table 3. Panelist scores of different ratios of blended shortening (F4S6 and F45S55) compared with the control (PH) |
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Tests |
Blended fatty |
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F4S6 |
F45S55 |
Control |
LSD |
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Taste(10) |
8.28±0.18ª |
7.85±0.26ab |
7.28±0.42b |
0.84 |
Color(10) |
8.71±0.28a |
8.85±0.26a |
8.28±0.28a |
0.76 |
Odor(10) |
8.00±0.37a |
8.28±0.47a |
6.85±0.34b |
1.11 |
Texture(10) |
8.71±0.28a |
8.57±0.20a |
8.57±00.3a |
0.81 |
Overall acceptability |
8.42±0.23a |
8.39±0.23a |
7.75±0.14b |
0.57 |
Means ± standard division of triplicate trials
Within a column means having the same superscript letters are not significantly different at 1%level
Conclusion
Regarding the thermal properties of different samples (SO, F4S6, F45S55), the results observed that melting occurs at approximately 27, 39, and 48 for soybean oil as a control sample, F4S6, and F45S55, respectively. Therefore, the addition of fully hydrogenated soybeans increases the melting point of oil. For the melting enthalpy ΔHm, the lowest was for PH, and the highest ΔHm was for F4S6. The GC data represented the highest value of C18: I found in FH followed by PH, F45S55, and then F4S6 85.07, 23.64, 14.13 and 13.35 %w, respectively. The data illustrated that F4S6 and F45S55 had no trans fatty acid (TFA) of oleic acid (C18:1T) compared with the control (PH), which had around 16.976. However, F4S6 and F45S55 had very small amounts of trans fatty acid of linoleic acid (C18:2T) compared with control (PH), which recorded 0.09, 0.09, 0.01 and 0.49 %w, respectively. In general, the blended fatty from soybean oil and fully hydrogenated soybean oil (F4S6 and F45S55) improved sample sensory properties compared with the control.
Acknowledgments: we are so grateful to professor dr. Mazzanti from Dalhousie University for his kindly academic support during this work.
Conflict of interest: None
Financial support: This manscript work has been funded by Helwan University and Dalhousie University.
Ethics statement: None