Abstract
The last three steps of the alginate production process were studied:conversion of alginic acid to sodium alginate, drying, and milling. Threemethods were used to follow the conversion reaction: measuring the pH (a) intheethanol-water liquid of the reaction mixture, (b) after dissolving a sample ofthe fiber taken from the reaction mixture, (c) after dissolving the driedsodiumalginate obtained from the reaction. To obtain a neutral dried sodium alginate,in the first method the pH should be adjusted to 9, and in the second the pHshould be adjusted to 8. The best method to control the reaction was todissolvea sample of the fiber and adjust the pH to 8. The best proportion to reach thecritical point, where pH just begins to rise, was 0.25 parts of sodiumcarbonateto 1 part of alginate in the initial dry algae. A pH above 7 may produce abreakdown of the molecule, reducing significantly the viscosity of the finalalginate. Four different temperatures were used to dry the alginate: 50, 60,70,and 80 °C. Drying time to reach 12% moisture ranged from 1.5h at 80 °C to 3 h at 50°C. The best drying temperature was 60 °C for2.5 h. The effect of drying temperature on alginate viscosity wasdependent on the alginate type. Low and medium viscosity alginates were notsignificantly affected, but alginate with high viscosity was reduced by 40 to54% using the temperature range of 60 to 80 °C. A fixed hammermill was used to reduce the particle size of the dried sodium alginate.Particlesize measurements showed that after a first milling the product contained 76%large particles (20–60 mesh) and 24% fine particles (80–120 mesh).After a third milling the product still contained 42.9% large particles. Nosignificant effect was found on alginate viscosity because of the millingsteps.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Baranov V.S., Locev V.N., Guernet N.A., Kuchumova R.P. and Kuchumov A.M. 1967. Method to obtain sodium alginate. USSR Patent 707, 561.
Haug A., Larsen B. and Smidsrød O. 1963. The degradation of alginates at different pH values. Acta Chem. Scand. 17: 1466-1468.
Haug A. 1964. Composition and properties of alginates. Report 30. Norwegian Inst. of Seaweed Research, Trondheim, Norway,123 pp.
Hernández-Carmona G., McHugh D.J., Arvizu-Higuera D.L. and Rodríguez-Montesinos Y.E. 1998. Pilot plant scale extraction of alginate from Macrocystis pyrifera. 1. Effect of pre-extraction treatments on yield and quality of alginate. J. appl. Phycol. 10: 507-513.
Hernández-Carmona G., McHugh D.J. and López-Gutiérrez F. 1999. Pilot plant scale extraction of alginate from Macrocystis pyrifera. 2. Studies on extraction conditions and methods of separating the alkaline-insoluble residue. J. appl. Phycol. 11: 493-502.
King A.H. 1983. Brown seaweed extracts (alginates). In: Glicksman M. (ed.), Food Hydrocolloids. CRC Press, Boca Raton, Florida, USA, pp. 115-188.
McHugh D.J., Hernández-Carmona G., Arvizu-Higuera D.L. and Rodríguez-Montesinos Y.E. 2001. Pilot plant scale extraction of alginate from Macrocystis pyrifera. 3. Precipitation, bleaching and conversion of calcium alginate to alginic acid. J. appl. Phycol. 13: 471-479.
StatSoft, Inc. 1995. StatSoft, Inc., 2325 East 13th Street, Tulsa 74104, OK,, 1878 pp.
Zar J.H. 1984. Biostatistical Analysis. Prentice-Hall, Inc., Englewood Cliffs, New Jersey, 718 pp.
Zvered D.I., Afonin B.P., Sendzimerzh A.L., Andrievskiy Y.P., Petzakova T.N. and Andrievskaya V.V. 1969. Recovery of alginates from brown algae. USSR Patent 229, 213.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Hernández-Carmona, G., McHugh, D.J., Arvizu-Higuera, D.L. et al. Pilot plant scale extraction of alginates from Macrocystis pyrifera 4. Conversion of alginic acid to sodium alginate, drying and milling. Journal of Applied Phycology 14, 445–451 (2002). https://doi.org/10.1023/A:1022372807813
Issue Date:
DOI: https://doi.org/10.1023/A:1022372807813