Open-access Chitosan as flocculant agent for clarification of stevia extract

Abstract

Stevia is used as a sweetener due to its low calorific value and its taste, which is very similar to that of sucrose. After extraction from dried leaves, stevia extract is dark in colour, and therefore needs to be whitened to increase acceptance by consumers. In this study we tested chitosan, a cationic polyelectrolyte, as flocculant agent for the whitening of the Stevia extract. Positive charges of chitosan can interact electrostatically with a counter-ion, sodium tripolyphosphate (TPP), and then chitosan precipitates. A factorial design was used to study the whitening process, in which Glycosides Removal, Colour Removal, Turbidity Removal and Soluble Solids Removal were evaluated. The studied factors were Chitosan Mass and pH of the TPP solution. The results showed that chitosan is a good flocculant agent, being able to flocculate both the glycosides and the pigments that make the extract coloured.

Stevia; sweeteners; chitosan; flocculation; clarification


Chitosan as flocculant agent for clarification of stevia extract

Silvia P. D. de OliveiraI; Cynthia R. A. MahlI; Márcia R. SimõesI; Classius F. da SilvaII

ICentro de Engenharias e Ciências Exatas, UNIOESTE

IICentro de Ciências Exatas e da Terra, UNIFESP

ABSTRACT

Stevia is used as a sweetener due to its low calorific value and its taste, which is very similar to that of sucrose. After extraction from dried leaves, stevia extract is dark in colour, and therefore needs to be whitened to increase acceptance by consumers. In this study we tested chitosan, a cationic polyelectrolyte, as flocculant agent for the whitening of the Stevia extract. Positive charges of chitosan can interact electrostatically with a counter-ion, sodium tripolyphosphate (TPP), and then chitosan precipitates. A factorial design was used to study the whitening process, in which Glycosides Removal, Colour Removal, Turbidity Removal and Soluble Solids Removal were evaluated. The studied factors were Chitosan Mass and pH of the TPP solution. The results showed that chitosan is a good flocculant agent, being able to flocculate both the glycosides and the pigments that make the extract coloured.

Keywords: Stevia, sweeteners, chitosan, flocculation, clarification.

Introduction

The leaves of the sweet herb from Paraguay, Stevia rebaudiana Bertoni, produce an alternative to sucrose with the advantage that stevia sweeteners are natural plant products, non-metabolizable, non-fermentable, anti-carcinogenic, anti-plaque and non-toxic to humans. In addition, the functional and sensory properties of stevia are superior to those of many other high-potency sweeteners[1]. Global markets for Stevia is pegged at around $ 500 million with Japan alone accounting for $ 200 million[2].

According to Crammer and Ikan[3], the leaves of the Stevia rebaudiana plant contain a complex mixture of diterpenes, triterpenes, tannins, stigmasterol, volatile oils and eight sweet diterpene glycosides. They are Stevioside, Steviolbioside, Rebaudiosides A, B, C, D and E and Dulcoside A (Figure 1). Rebaudioside A is more stable and much sweeter and tastes better than Stevioside. Rebaudioside E is as sweet as Stevioside, and Rebaudioside D is as sweet as Rebaudioside A, while the remaining diterpene glycosides are not as sweet as Stevioside. Although there is a molecule called Stevioside, it is customary to employ the term Steviosides to the set of sweet compounds.


The relative sweetness of these diterpenes glycosides depends on concentration and the environment. Collectively they make stevia 100 to 300 times sweeter than sucrose[4].

Dried leaves are infused in hot water or alcohol (ethanol or methanol) to obtain their extract, which is a solution with brownish colloidal particles. This extract must be clarified prior to commercialization. One method of clarification is precipitation of impurities by hydroxides and fractional extraction of glycosides with butanol or methanol[5,6]. These solvents are usually toxic to humans and after clarification they have to be totally removed from the sweetener. Others processes have been used in the clarification, like filtration[7,8], flocculation with polyelectrolytes[9,10] and adsorption[11,12].

Flocculation appears as a promising process since it is safe and free of toxic solvents. Bunhak et al.[10] investigated two polyelectrolytes on the clarification of Stevia extract using two commercial flocculants available in Brazil, NOVUSTM CE2666 (cationic polyelectrolyte) and BETZDEARBORNTM F11 (anionic polyelectrolyte). The best result was obtained when the anionic polyelectrolyte was used, achieving a turbidity removal of equivalent to 97%. Furthermore, Fernandes et al.[9] tested the cactus Cereus peruvianus as an alternative natural resin to clarify the stevia extract. This cactus behaved like a strong acid resin and eliminated about 95% of the colour and turbidity of stevia.

Natural polymers, such as chitosan, have advantages because they are cheaper and safer from the point of view of food. The main properties of this polysaccharide are: bioactivity, biodegradability, biocompatibility, reactivity of deacetylated amino groups, selective permeability, polyelectrolyte action, ability to form gel film, chelation ability and adsorption capacity[13,14].

Chitosan has unique properties among biopolymers, especially due to the presence of primary amino groups. Chitosan has been used for the chelation of metal ions in near-neutral solution, the complexation of anions in acidic solution (cationic properties due to amine protonation), the coagulation of negatively charged contaminants under acidic conditions, and for precipitative flocculation at pH above the pKa of chitosan. The coagulation and flocculation properties can be used to treat particulate suspensions (organic or inorganic) and also to treat dissolved organic materials (including dyes and humic acid). Moreover, chitosan has characteristics of both coagulants and flocculants agents: high cationic charge density, long polymer chains, bridging of aggregates, and precipitation in neutral or alkaline pH conditions[15]. These properties have been exploited for the design of coagulation-flocculation processes applied, for example, to sewage treatment[16], industry wastewater[17], piggery wastewater treatment[18], paper-recycling wastewater[19].

According to Guibal et al.[15], stoichiometry and charge restabilization were determined for the coagulation of humic acid solutions, kaolin suspensions, and organic dyes with chitosan, indicating charge neutralization as the dominant mechanism for removal. Charge patch destabilization and bridging mechanisms were inferred in organic suspensions, based on the effects of the apparent molar mass of the chitosan preparations and effectiveness of sub-stoichiometric doses of chitosan.

This work aims to study the clarification of aqueous stevia extract in a batch reactor using chitosan as flocculant agent. Factorial design was used to study the process and the studied factors were: pH of the sodium tripolyphosphate solution and the Chitosan Mass.

Material and Methods

Material

Stevia leaves were kindly supplied by Steviafarma S.A. (Maringá, Brazil). Chitosan (viscosimetric molar mass = 105 kDa; degree of deacetylation = 81.61 ± 1.05%) was purchased from Polymar (Fortaleza, Brazil). All other chemicals (phenol, sulfuric acid, sodium tripolyphosphate) were of analytical grade used without further purification. The solutions were prepared using distilled water.

Preparation of chitosan solution

The chitosan solution, with a concentration of 0.66% w/w, was obtained by dissolving chitosan powder in 0.25 vol. % acetic acid solution and magnetic stirring for at least 24 hours.

Preparation of aqueous stevia extract

The extract was prepared by mixing one part of stevia leaves with nine parts of water. For such purpose, water was heated to 55 ºC and then mixed with stevia leaves, with the mixture being allowed to steep for 1 hour. After cooling, the extract was filtered through a paper filter and centrifuged at 3000 rpm for 15 minutes.

Clarification experiments

Ten milliliters of Stevia extract was added in 5 mL (3.3 g of chitosan) or 10 mL (6.6 g of chitosan) of chitosan solution and kept under magnetic stirring at room temperature for 15 minutes. Then ten milliliters of sodium tripolyphosphate (TPP) solution (1% w/v) was added and stirred for 15 minutes. The pH of TPP solutions was adjusted to the required value by the addition of concentrated HCl. The suspension was left to decanter for 15 minutes and then was centrifuged at 3000 rpm for 15 minutes and the supernatant was analyzed. A 22 factorial design without central points was performed to evaluate the importance of the pH of TPP solution and Chitosan Mass on the clarification process of stevia extract. Table 1 summarizes these factor and their respective levels. The pH and the polyelectrolyte mass (Chitosan Mass) are important factors in flocculation processes with polyelectrolytes. Our preliminary studies, also using the response surface methodology showed that, specifically in the case studied, the concentration of chitosan had no significant effect. Thus, the levels chose in this factorial design were also determined from our previous experience. All the essays were performed in triplicate and according to the Table 2.

Parameters such as the Colour Removal (CR), Turbidity Removal (TR), Total Glycosides Removal (GR) and Soluble Solids Removal (SR) were evaluated employing Equation 1:

(1)

The subscripts "BEFORE" and "AFTER" relate to the properties before and after the clarification process, respectively. Properties like optical absorbancies measured at 420 and 670 nm were correlated with the Colour Removal (CR) and Turbidity Removal (TR) parameters, respectively[20]. Each parameter was calculated with respect to a solution having the same pH value.

According to Costa et al.[21], it is possible to relate the concentration of total stevia glycosides with the concentration of total carbohydrate which can be obtained via the phenol/sulphuric acid method. The quantities of free sugars or sugar oligomers present in the extract are insignificant. The adsorption percentage of stevia glycosides was also calculated by Equation 1 using the concentration of total stevia glycosides as a property. Absorbancies were analyzed employing a spectrophotometer (Shimadzu UV 1601 PC, Japan). The total soluble solids in a given solution were determined by refractometer (Atago, Japan). This enabled the soluble solids properties, called ºBrix, to be obtained. The total percentage adsorption of soluble solids was calculated via Equation 1 using the measured ºBrix as a given property.

Statistical analysis

The statistical calculations were performed using the Statistica® software packages.

Results and Discussion

Table 2 shows the experimental conditions used in this study with the results for Glycosides Removal (GR), Colour Removal (CR), Turbidity Removal (TR), and Soluble Solids Removal (SR).

The effects estimates for each variable were determined and reported in Table 3. An estimate effect is obtained by evaluating the difference in process performance caused by a change from the low (-1) to the high (+1) level of the corresponding factor[22]. A small p-value suggested that the coefficient was a large signal in comparison to the noise because it was too large to have arisen by chance alone. In this case, p < 0.05, suggested significance at the 0.05 level. This also corresponded to a 95% confidence level for a test of the hypothesis that the effects in question were equal to zero.

The R-squared (R2) value provides a measure of how much of the variability in the observed response values could be explained by the experimental factors and their interactions. Models with R-square values above 0.9 are considered excellent and can explain most of the variation in the response. Actually, models with R-squared near the unity present better response predictions, minimizing the difference between the predicted and observed values[22]. According to this statement, only the GR presented an adequate predicting model. Every parameter is discussed separately as following.

Glycosides Removal (GR)

Table 3 shows the effect of the factors on the percentage of Glycosides Removal (GR). The average effect was about 44.56%, which is not acceptable since stevia glycosides should not be flocculated by the flocculant agent. Our purpose is only to clarify the extract, so it is important to minimize the flocculation of stevia glycosides, i.e., the flocculant agent must be able to flocculate substances that give colour to the extract without flocculating stevia glycosides.

The pH showed negative effect on the percentage of the GR what is desirable as it must be minimized. However the effect of pH can not be analyzed alone, since the interaction between Chitosan Mass and pH was significant (p < 0.05). Figure 2 shows the interactions between the pH and Chitosan Mass. The Vertical bars in the Figure 2 denote 0.95 confidence intervals.


According to the Figure 2, at the pH = 7.5 (the lower level, i.e., -1), the highest level of Chitosan Mass (6.6 g) presented the lowest GR values. On the other hand, at pH = 9.3 (the higher level, i.e., +1), the highest level of Chitosan Mass (6.6 g) presented the highest GR values. So, there is a contrary behavior, which characterizes the interaction between Chitosan Mass and pH. This behavior can also be seen in the response surface presented in Figure 3. As expected, the lowest GR value occurs on the lower Chitosan Mass and higher pH.


Guibal et al.[15] studied the coagulation of an anionic dye whit chitosan. For a given dye concentration, increasing the chitosan concentration decreased the residual concentration of the dye up to an upper limit of chitosan concentration. Above this limit concentration (optimum chitosan concentration, OCC) the addition of an excess of chitosan resulted in a re-stabilization of the dye and a decrease in coagulation efficiency. This optimum chitosan dosage (OCC) strongly depended on both the initial pH and the dye concentration. The OCC provided a precise measurement of the effective chitosan concentration, establishing the stoichiometric ratio between the functional groups of the dye and the biopolymer. Therefore, the OCC could explain the interaction between the pH and Chitosan Mass. At one of the pH, the Chitosan Mass is below the OCC, and at the other pH, the Chitosan Mass is above the OCC.

Colour Removal (CR)

The CR values (Table 2) were higher than the one obtained by Bunhak et al.[10] using anionic or cationic polyelectrolytes in order to clarify the stevia extract. The highest Colour Removal verified by Bunhak et al.[10] was 79.2% and 72.2% for anionic and cationic polyelectrolytes, respectively. Moreover, the average effect was about 87.25% (Table 3) and only the pH presented significant effects. The negative effect of pH was also verified by Bunhak et al.[10] with the cationic synthetic polyelectrolyte (NOVUSTM CE2666) for the pH ranging between 8 and 9. On the other hand, they found positive effect on the Colour Removal when the pH ranged between 9 and 10.

Fernandes et al.[9] studied the cactus Cereus peruvianus as an alternative natural resin to clarify the original stevia extract. This cactus behaves as a strong acid resin and reached about 95% of CR and the pH was kept bellow 3.

Turbidity Removal (TR)

None of the variables (Chitosan Mass and pH) had significant effect, even the interaction between them. Only the average effect was significant (p < 0.05). The average effect was about 87% that is very close to the 84% which was obtained by Fernandes et al.[9]. However, they used concentration of resin from 2 to 10% w/v, and our results were obtained with just 0.66% w/v chitosan solution.

Soluble Solids Removal (SR)

Concerning the SR, the average effect was about 55.19% (Table 3). The Chitosan Mass was the only significant variable for the SR (p < 0.05), so SR increases about 11.86% when Chitosan Mass increases from 3.3 (-1) to 6.6 g (+1).

The soluble solids content observed in stevia extract were from 1.5 to 3.0 ºBrix after clarification with chitosan as flocculant agent. Fernandes et al.[9] found similar values (2.0 and 2.7 ºBrix) in their study of the cactus Cereus peruvianus on colour removal of the stevia extract.

Mahl et al.[12] tested alginate beads as adsorbent in clarification of stevia extract. They state that an ideal adsorbent for the clarification process must be capable of removing both colour and turbidity, but not removing the glycosides. The clarification was evaluated by determining the ratio of colour removal to glycosides removal. High ratios are associated to process with good performance. This ratio was also used to evaluate the performance of the experiments carried out in this work as shown in Table 4. Based on CR values it is clear that all the experiments lead to good results. Although the experiment 2 had the lowest percentage of CR, such experiment showed the lowest GR. So, it was considered the best conditions to achieve the objectives of this study. The best results were obtained at a pH value of 9.3 and Chitosan Mass of 3.3 g. The values of the CR/GR ratio were very similar to those obtained by Mahl et al.[12]. However, this ratio can not be evaluated alone, because it is not observed CR values greater than 70%.

The experiment 1 would be considered the best results since the CR was highest, but the GR was also high. For the experiment 3, at the same pH 7.5, when the Chitosan Mass increases from 3.3 to 6.6 g, the GR decreases. A possible explanation for this behavior can be associated to chitosan molecules interactions with both glycosides and TPP. It is also probable that there is a competition between each other (glycosides and TPP).

According to Renault et al.[23], the mechanisms of coagulation/flocculation involved in the removal of dissolved and particulate contaminants using chitosan often cited are charge neutralization, adsorption (related to protonated amine groups), precipitative coagulation, bridge formation (related to the high molar mass of biomacromolecules) and electrostatic patch. The mechanism is the following: coagulation by charge neutralization destabilizes colloidal impurities and transfers small particles into large aggregates (bridge formation) and adsorbs dissolved organic substances onto the aggregates by an adsorption mechanism which can then be removed easily by filtration and sedimentation.

In the clarification of stevia extract with chitosan, after the addition of chitosan to the stevia extract, it was not observed turbidity of the medium, nor the formation of any particles, indicating that there is no electrostatic interaction between chitosan and stevia extract compounds (no charge neutralization). It is well established ionic crosslinking of chitosan with TPP in order to produce chitosan nanoparticles. On the other hand, increasing the pH of the medium also may promote the precipitation of chitosan. The removal of some pigments and steviosides from extract occurred during the formation of these nanoparticles and their subsequent aggregation and precipitation. Then, the results suggest that the precipitative coagulation is the most relevant mechanism in the clarification of stevia extract, but the bridging formation must also be occurring.

Conclusions

Chitosan acted as one good flocculant agent in the clarification of Stevia extract. The Colour Removal (CR) values were from 78 to 93%, which is very good for clarification process of stevia extract. One response surface was also obtained for Glycosides Removal (GR) as function of pH and Chitosan Mass. The pH showed a significant effect on the Colour Removal (CR) and Glycosides Removal (GR). while the Chitosan Mass affected only the Soluble Solids Removal (SR). The Turbidity Removal (TR) was not affected by the two variables. Thus, according to the CR/GR ratio, the best results were observed for experiment 2, in which the Chitosan Mass is equal to 3.3 g and pH of TPP is equal to 9.3. Moreover, this experiment also is more economic considering the chitosan use. The use of a biodegradable polymer from a renewable resource and less aggressive for the environment is an important criterion for future developments.

Reenviado: 02/01/12

Aceito: 05/01/12

References

  • 1. Brandle, J. E.; Starratt, A. N. & Gijzen, M. - Can. J. Plant Sci., 78, p.527 (1998). http://dx.doi.org/10.4141/cjps10086
  • 2. Rajagopal, R. - "Stevia as an alternative sweetener - Promise and Challenges", KnowGenix & Centre for Management Technology (2009). Disponível em: <www.steviaworldforum.com/steviapaper/SteviaPosition-P.pdf>. Accesso em: 5 fev. 2011.
  • 3. Crammer, B. & Ikan, R. - "Progress in the Chemistry and Properties of Rebaudiosides", in: Developments in Sweeteners, v.3, T. H. Grenby (ed.), Elsevier Applied Science, London (1987).
  • 4.Phillips, K. C. - "Stevia: Steps in Developing a New Sweetener", in: Developments in Sweeteners, v.3, T. H. Grenby (ed.), Elsevier Applied Science, London (1987).
  • 5. Takamura, K.; Kawaguchi, M. & Isono, C. - "Stevioside from Stevia rebaudiana", Japanese Patent No 52047961 (in japanese) (1977).
  • 6. Abou-Arab, A. E., Abou-Arab, A. A. & Abu-Salem, M. F. - African Journal of Food Science, 4(5), p.269 (2010).
  • 7. Silva, F. V.; Bergamasco, R.; Andrade, C. M. G.; Pinheiro, N.; Machado, N. R. C. F.; Reis M. H.; Araújo, Á. A. & Rezende, S. - Int. J. Chem. React. Eng., 5, p.A40 (2007). http://dx.doi.org/10.2202/1542-6580.1443
  • 8. Reis, M. H. M.; Silva, F. V.; Andrade, C. M. G.; Rezende, S. L.; Maciel, M. R. w. & Bergamasco, R. - J. Food Proc. Eng., 32, p.338 (2009).
  • 9. Fernandes, L. M.; Pereira, N. C.; Mendes, E. S.; Lima, C. O. M. & Costa, S. C. - Acta Sci., 23, p.1369 (2001).
  • 10. Bunhak, E. J.; Mendes, E. S.; Pereira, N. C. & Costa, S. C. - Acta Sci., 24, p.1643 (2002).
  • 11. Mantovaneli, I. C. C.; Ferretti, E. C.; Simões, M. R. & Silva, C. F. - Braz. J. Chem. Eng., 21, p.449 (2004). http://dx.doi.org/10.1590/S0104-66322004000300009
  • 12. Mahl, C. R. A.; Oliveira, S. P. D.; Simões, M. R. & Silva, C. F. - Adsorption Sci. & Tech., 28, p.189 (2010).
  • 13. Tharanathan, R. N. & Kittur, F. S. - Crit. Rev. Food Sci. & Nutr., 43, p.61 (2003). http://dx.doi.org/10.1080/10408690390826455
  • 14. Synowiecki, J. & Al-Khatteb, N. A. A. - Crit. Rev. Food Sci. Nutr., 43, p.145 (2003). http://dx.doi.org/10.1080/10408690390826473
  • 15. Guibal, E.; Vooren, V. M.; Dempsey, B. A. & Roussy, J. - Sep. Sci. Tech., 41, p.2487 (2006).
  • 16. Zeng, D.; wu, J. & Kennedy, J. F. - Carbohydr. Polym., 71, p.135 (2008). http://dx.doi.org/10.1016/j.carbpol.2007.07.039
  • 17. Renault, F.; Sancey, B.; Charles, J.; Morin-Crini, N.; Badot, P-M; winterton, P. & Crini, G. - Chem. Eng. J., 155, p.775 (2009). http://dx.doi.org/10.1016/j.cej.2009.09.023
  • 18. Godos, I.; Guzman, H. O.; Soto, R.; García-Encina, P. A.; Becares, E.; Muñoz, R. & Vargas, V. A. - Biores. Tech., 102, p.923 (2011). http://dx.doi.org/10.1016/j.biortech.2010.09.036
  • 19. wang, J.-P.; Chen, Y.-Z.; Ge, X.-w & Yu H.-Q. - Coll. & Surf. A: Phys. Eng. Asp., 302, p.204 (2007).
  • 20. Fuh, w. S. & Chiang, B. H. - J. Food Sci., 55, p.1454 (1990). http://dx.doi.org/10.1111/j.1365-2621.1990.tb03956.x
  • 21. Costa, S. C.; Nishiyama, P.; Kusumoto, I. T.; Vieira, L. G. E. & Alavarez, M. - Arq. Biol. Tecn., 34, p.425 (1991)
  • 22. Haaland, P. D. - "Experimental design in biotechnology", Marcel Dekker Inc, New York (1989).
  • 23. Renault, F.; Sancey, B.; Badot, P.-M. & Crini, G. - Eur. Pol. J., 45, p.1337 (2009). http://dx.doi.org/10.1016/j.eurpolymj.2008.12.027

Publication Dates

  • Publication in this collection
    30 Oct 2012
  • Date of issue
    2012
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