The rheological properties of six mucilage solutions (Guar Gum, Locust Bean Gum, Tamarind Gum, Flaxseed Gum, Artemisia Sphaerocephala Krasch Gum and Cassia Gum) have been examined. It was found that all six gums could be classified into three different types according to the changes of viscosity with increasing shear rate. Steady shear viscous properties in a range of shear rate from 0.1 to 100 s -1 were investigated in the provision of mucilage concentration, pH, temperature and salts. A non-Newtonian shear-thinning behavior was observed. The data of viscosity-shear successfully correlated Power law model. Apparent viscosity was apparently dependent on mucilage concentration increasing significantly as mass fraction went up. A marked dependence of viscosity on temperature was also observed; as temperature increased, the viscosity decreased sharply. The value n of flaxseed gum is minimum, which means it behaves the greatest shear-thinning properties. Both Guar gum and Tamarind gum possessed better acid-proof and alkali-proof advantages. The flow activation energy of ASKG is 4.3 kcal which is higher than other gums so that the influence of temperature on characteristics of viscosity is stronger. The mechanical spectra in the linear viscoelasticity region were studied in the temperature range from 20 °C to 90 °C, at a frequency range from 0.1 to 10 Hz. It was observed that Both elastic modulus G' and viscous modulus G" behaviors were found to be dependent on temperature and frequency. What have been investigated in this work could provide guidance for practical application in the field of food industry.
Natural gums are polysaccharides consisting of multiple sugar units linked together to large molecules. They have diverse applications as thickeners, emulsifiers, viscosifiers, sweeteners etc. [
The natural gums are categorized based on their origins, behaviors and chemical structures. Gums are known as complex polysaccharides from various sources, e.g. plant seeds, plant exudates, tree or shrub exudates, sea weed extracts, bacteria, and animal sources [
Food gums are used in many formulations for their viscosity-imparting effect on aqueous media, providing acceptable texture to food products [
According to the factors of popularity, application, price and commercial values, we selected six plant-based seed gums (Guar Gum, Locust Bean Gum, Tamarind Gum, Flaxseed Gum, Artemisia Sphaerocephala Krasch Gum and Cassia Gum) to explore the generality and particularity between various plant-based seed gums so as to attain the desired functional properties as well as to provide guidance for practical application in the process of food production.
In this work, we comprehensively studied the rheological properties of six plant-based seed gums.
The aim of this research is to demonstrate the different rheological properties of Guar Gum, Locust Bean Gum, Tamarind Gum, Flaxseed Gum, Artemisia Sphaerocephala Krasch Gum and Cassia Gum for their further application in food industry.
The dry powders of six plant-based seed gums (Guar Gum, Locust Bean Gum, Tamarind Gum, Flaxseed Gum, Artemisia Sphaerocephala Krasch Gum and Cassia Gum) were purchased from Hennan Huayue chemical products Co., Ltd. (China). Aqueous solutions of six plant-based seed gums were prepared by carefully adding the required amount of dry powder into a vortex formed by mixing with a mechanical stirrer continuously for 30 min at a constant temperature of 60˚C. After stirring, the samples were stored at 25˚C for 4 h for further hydration. Then, the samples were stored at 4˚C to prevent degradation due to bacterial growth. All tests were completed within 24 h after sample preparation.
Rheological measurements of the six plant-based seed gums were performed using MCR101 (Austria) rheometer with parallel plate measurement system. The temperature was controlled by a water bath connected to the Peltier system in the bottom plate. A steel cone geometry (50 mm diameter, 47 µm gap) was chosen for the rheological measurements. The rheological measurements include steady-state rheology analysis, effects of concentration, temperature, PH, salt on viscosity and dynamic rheological experiment. Three replicates are carried out in the experiments.
The flow curves of the six plant-based seed gum samples were studied at 25˚C over the shear rate range of 0.1 - 100 s−1 to measure the apparent viscosity. This shear rate range covers the flow of a number of non-Newtonian fluid foods in many food operations [
τ = k γ n (1)
where τ is the shear stress (Pa), γ is the shear rate (s−1), K is consistency index (Pa・Sn), and n is the flow behavior index(dimensionless).
Power Law fluids can be subdivided into three different types of fluids based on the value of their flow behavior index: n < 1 pseudoplastic fluid or shear-thinning fluids, n = 1 Newtonian fluid (where apparent viscosity is constant regardless of imposed stress) and n > 1 dilatant or shear thickening fluids.
The effect of concentration on apparent viscosity of each gum was measured by steady shear rheological measurements in concentrations of 0.1%, 0.3%, 0.5%, 1%, 1.5% and 2% (w/w) respectively. Averages of three repeat experiments were considered for data analysis.
Solution samples were loaded onto the plate of the rheometer and were equilibrated at 20˚C. The samples were then heated from 20˚C to 90˚C at a rate of 5˚C/min. The relationship of viscosity with temperature of fluid food is taken to satisfy the Arrhenius relationship:
η = η 0 e ( E a / R ) (2)
where, η0 is the frequency factor (Pa・Sn), Ea represents the activation energy (KJ/mol), R is the gas law constant (R = 8.314 J/mol∙K), and T is the absolute temperature (K). The flow activation energy is calculated using the Arrhenius equation.
The initial pH values of the solutions were adjusted to 2, 4, 6, 8, 10, and 12 for each sample by adding either HCl (0.1 mol/L) or NaOH (0.1 mol/L) when required. Then, the apparent viscosity was tested at 25˚C. Each sample was measured in triplicate to ensure quantitative accuracy.
To study the effect of salt on viscosity of gums, the amounts of NaCl, CaCl were added at a range of 0.2 - 2 g/dl and completely dissolved as well. All tests were performed at 25˚C. Three replicates were carried out in the experiments.
The viscosity properties of food are determined by the dynamic rheological experiment. G' is storage modulus expressing the elastic of food, loss modulus G" expresses the viscous of food. The experiments were performed at least in triplicate. Loss tangent tan δ = G"/G'.
Solution samples were loaded onto the plate of the rheometer and were equilibrated at 20˚C. The samples were then heated from 20˚C - 90˚C at a rate of 5˚C/min and held at 90˚C for 20 min and then cooled to 20˚C. These cooled samples were equilibrated at 20 for 10 min. The tests were performed at a frequency of 1 Hz. The amplitude of the strain in these tests was selected to be 1% according to the strain sweep results (date not shown) in order to be within the linear viscosity region.
The frequency sweep tests were performed at 25˚C over the angular frequency range of 0.1 - 10 rad/s. The strain amplitude for the frequency sweep measurements was selected as 1%.
The time sweep tests were measured at 25˚C at the range of 0 s - 2000 s to observe the complex modulus changes. The strain amplitude was selected to be 1% in the linear viscosity region.
All the experiments were performed on triplicate samples and values were expressed as mean values ± SD. Differences between mean values were conducted using the one-way analysis of variance (ANOVA) by SPSS 19.0 software. Differences were statistically significant at p < 0.05.
As shown in
gum. The Artemisia Sphaerocephala Krasch gum and Cassia gum were the least viscous. This means the first two varieties could behave higher viscous at low concentration. Based on the flow curve of six-plant based gums, they could be subdivided into three different types, which can be considered during the process of ready-food production. Thus, the Flaxseed gum and Locust bean would have an advantage in the provision of viscosity.
The difference of apparent viscosity between six-plant seed gums is mainly related to their Molecular weight as well as the ability to interact with water to form molecular entanglements. The flaxseed gum consists of protein, polysaccharides which include rhamnose, xylose and galactose [
The plot of the shear stress versus shear rate is shown in
| Variety | K | n | R2 |
|---|---|---|---|
| Flaxseed Gum | 15.046 | 0.283 | 0.9579 |
| Locust Bean Gum | 11.577 | 0.308 | 0.9664 |
| Tamarind Gum | 12.87 | 0.497 | 0.9892 |
| Guar Gum | 1.671 | 0.466 | 0.9876 |
| Cassia Gum | 0.468 | 0.731 | 0.9966 |
| Artemisia Sphaerocephala Krasch Gum | 0.102 | 0.925 | 0.9915 |
and the highest n value, this is to say that the apparent viscosity of ASKG has little changes with increasing shear rate.
Rheological behaviors are directly related to the structural features. The mass fraction plays a vital role affecting the apparent viscosity of six gums. As can be seen from
As the concentration of flaxseed gum and locust bean gum is less than 0.3%, its viscosity keeps invariable with raising shear rate exhibiting the characteristics of Newtonian fluid (
The relationship between apparent viscosity and temperature of six types of gums is shown in
| Flaxseed Gum | Locust Bean Gum | Tamarind Gum | Guar Gum | Cassia Gum | Artemisia Sphaerocephala Krasch Gum | |
|---|---|---|---|---|---|---|
| Ea(kcal) | 1.37 | 1.44 | 2.15 | 2.41 | 3.71 | 4.30 |
| R2 | 0.9906 | 0.9930 | 0.9978 | 0.9961 | 0.9996 | 0.9946 |
applied to food products with high demand for little viscosity changes at a wide range of temperature. Compared with FG and LBG, Guar gum and Tamarind gum have worse thermal stability. The apparent viscosity of Artemisia Sphaerocephala Krasch gum and Cassia gum had been affected severely with the change of temperature.
The flow activation energies (Ea) of six plant-based seed gums are calculated by the equation logη = logη0 + Ea/RT. Ea and R2 are showed in
The effect of pH on the steady-shear viscosity is shown in
bean gum goes up firstly then declined reaching its peak at pH 6 (
The effect of salt type (NaCl & CaCl2) on rheological properties of six plant- based seed gums was investigated and the experimental results regarding the effect on apparent viscosity are shown in
The region that complex modulus G* does keep consistent with the oscillation changes is named viscosity region [
with frequency at 25˚C for 2% mucilage solutions. It can be noticed that the elastic modulus G' for four gums (flaxseed gum, locust bean gum, guar gum and Tamarind gum) remains higher than the viscous modulus G" (G' > G"), which means that the mucilage solutions weak typical physical gel characteristics than viscosity properties. This behavior is probably dependent on mucilage concentration. But it has a different impact on the mucilage solutions of CG and ASKG. The Storage modulus G' is higher than Loss modulus G" at low frequency, then a cross-over appears at 4 Hz (G' = G"), where the system reverses subsequently the G' become lower than G", which means that the mucilage solutions behave as a solid at low frequency and turns liquid in the end.
The variation in storage modulus modulus G' and Loss modulus G" with time at 25˚C for 2% mucilage solutions are shown in
We have investigated the rheological behavior of six mucilage solutions from plant-based seed. Steady-shear viscosity measurements showed all the samples have a non-Newtonian shear-thinning behavior at different levels, which could be correlated to the shear rate by the power law model. We found that they could be subdivided into three different types according to the changes of viscosity with the increasing shear rate. The mass fraction made a great contribution to viscosity. Mucilage viscous solutions of all six gums were found obviously temperature-dependent and the apparent viscosity of six gums decreases with close rate at different extent as the temperature goes up. All mucilage solutions possessed better acid-proof and alkali-proof advantages except Cassia gum. A dependence of apparent viscosity with salt was also found. The apparent viscosity of six gums goes down with the increase of salt concentration, especially for CG and ASKG.
The dynamic flow properties in the linear viscosity region, as a function of temperature and frequency, were studied. Both elastic modulus G' and viscous modulus G" behaviors were found to be dependent on temperature and frequency. The Storage modulus G' of flaxseed gum and locust bean gum is always superior to Loss modulus G", which means that the elastic response to temperature sweep is continuously higher than the viscosity response. The Storage modulus G' of guar gum and tamarind gum is higher firstly than Loss modulus G", then become lower. However, the tan δ value of Cassia gum and Artemisia Sphaerocephala Krasch gum is always above 1, which indicates that mucilage solutions will show mainly viscous properties instead of an obvious tendency to form a gel. The elastic modulus G' for four gums (flaxseed gum, locust bean gum, guar gum and Tamarind gum) remains higher with the change of frequency than the viscous modulus G" (G' > G"). For CG and ASKG, the Storage modulus G' is higher
than Loss modulus G" at low frequency, then a cross-over appears at 4 Hz (G' = G"). All six mucilage solutions are not time-dependent fluids
Overall, what we have found above could support the application of plant-based seed gums in food industry; hence it is required in further work to study the application in different food products as well as the mechanisms.
This study was supported by the project sponsored by National Natural Science Foundation of China (No. 31571865) and Qingdao Technology Benefiting Project (No.15-9-2-107-NSH).
Chang, Y.B., Li, Y.F., Miao, Q.Q., Jiang, H.S. and Gao, X. (2017) Rheological Properties of Six Plant-Based Seed Gums. American Journal of Analytical Chemistry, 8, 690-707. https://doi.org/10.4236/ajac.2017.811051