Ion exchange kinetics of magnetic alginate ferrogel beads produced by external gelation

• Published in: Carbohydrate polymers Vol. 111; pp. 198 - 205
• Main Authors: Teixeira, Vânea Ferreira Torres, Pereira, Nádia Rosa, Waldman, Walter Ruggeri, Ávila, Ana Luiza Cassiano Dias, Pérez, Victor Haber, Rodríguez, Rubén Jesus Sánchez
• Format: Journal Article
• Language: English
• Published: Kidlington Elsevier Ltd 13.10.2014; Elsevier
• Subjects: Alginates - chemistry; Alginates - pharmacokinetics; Applied sciences; Biocatalyst support material; Biopolymer; Calcium - chemistry; Composites; Diffusion; Encapsulation; Exact sciences and technology; Forms of application and semi-finished materials; Glucuronic Acid - chemistry; Glucuronic Acid - pharmacokinetics; Hexuronic Acids - chemistry; Hexuronic Acids - pharmacokinetics; Ion Exchange; Iron - chemistry; Magnetic Phenomena; Particle Size; Polymer industry, paints, wood; Polymers - chemistry; Sodium - chemistry; Technology of polymers; Thermal degradation; Thermogravimetry - methods; Encapsulation; Biocatalyst support material; Diffusion; Biopolymer; Thermal degradation; Gelation; Iron; Alginates; Experimental study; Composite particles; Metal particle; Polyelectrolyte; Particle size distribution; Magnetic particles; Calcium ion; Oside polymer; Kinetics; Manufacturing; Aqueous solution
• ISSN: 0144-8617; 1879-1344
• DOI: 10.1016/j.carbpol.2014.04.009

•It was studied the preparation of Ca-alginate beads with iron addition with emphasis on the gelation kinetics mechanism.•The alginate concentration plays an important role in ionic exchange kinetics.•Saturation of the binding sites at the gel bead surface occurs for higher alginate concentrations.•Iron addition influenced the ion exchange kinetics and the thermal stability of composites. This paper reports on a study of the influence of sodium alginate concentration and iron addition on the ion exchange kinetics of calcium alginate ferrogel beads produced by external gelation. The calcium absorption and sodium release of the beads were fitted to Fick's second law for unsteady state diffusion in order to obtain the effective diffusion coefficients of Na+ and Ca2+. The dried beads were characterized concerning their thermal stability, particle size distribution and morphology. The gelation kinetics showed that an increase in alginate concentration from 1% to 2% increased the Ca2+ equilibrium concentration, but presented no effect on Ca2+ effective diffusion coefficient. Alginate concentration higher than 2% promoted saturation of binding sites at the bead surfaces. The addition of iron promoted faster diffusion of Ca2+ inside the gel beads and reduced the Ca2+ equilibrium concentration. Also, iron particles entrapped in the alginate gel beads promoted greater absorption of water compared to pure alginate gel and lower thermal stability of the beads. The main diffusion of Ca2+ into and Na+ out from the bead took place during the first 60min, during which almost 85–90% of the Ca2+ equilibrium concentration is achieved, indicating that this period is sufficient to produce a Ca-alginate bead with high crosslinking of the polymer network.