<p>A stable hydrogel beads based on the <i>Porphyridium cruentum</i> polysaccharide in combination with chitosan and a trivalent ion, Al<sup>3+</sup> or Fe<sup>3+</sup> were synthesized for the first time. Comparisons of the FTIR results for the beads obtained with Fe<sup>3+</sup> with the spectra of neat polysaccharides or the spectrum of the complex formed from chitosan and Fe<sup>3+</sup> showed changes in the infrared bands that reflect physical interactions among the components between the oxygen on the COO<sup>−</sup> within the <i>Porphyridium</i> polysaccharide and between the NH<sub>2</sub> groups within chitosan and Fe<sup>3+</sup>. XPS analysis of the beads showed that the typical bonds of each polysaccharide component were observed on the bead’s surface and that Fe-Oxides were formed. SEM analysis showed that bead morphology was characterized by a non-porous, smooth surface. In addition, viscosity showed extremely high viscosity at low shear rates, indicating a highly structured, viscoelastic soft solid. Rheological frequency sweeps further demonstrated that G′ ≫ G″ across the entire frequency range, confirming the hydrogel comprised a predominantly elastic, solid-like network that remains stable over time. Methylene blue sorption experiments revealed that equilibrium was reached after approximately 45&#xa0;min, with a maximum sorption yield of 86% obtained at 200 ppm methylene blue, whereas increasing the concentration to 500 ppm led to a decrease in sorption yield. The hydrogel beads were successfully reused for five consecutive adsorption–desorption cycles. Kinetic analysis showed that the pseudo-second-order model provided the best fit, and the adsorption isotherms were well described by both the Langmuir and Freundlich models.</p>

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Novel Preparation of Stable Hydrogels Based on the Red Alga Porphyridium cruentum and Their Use as Adsorbent

  • Oshrat Levy-Ontman,
  • Tali Lavi-Ohayon,
  • Adi Wolfson

摘要

A stable hydrogel beads based on the Porphyridium cruentum polysaccharide in combination with chitosan and a trivalent ion, Al3+ or Fe3+ were synthesized for the first time. Comparisons of the FTIR results for the beads obtained with Fe3+ with the spectra of neat polysaccharides or the spectrum of the complex formed from chitosan and Fe3+ showed changes in the infrared bands that reflect physical interactions among the components between the oxygen on the COO within the Porphyridium polysaccharide and between the NH2 groups within chitosan and Fe3+. XPS analysis of the beads showed that the typical bonds of each polysaccharide component were observed on the bead’s surface and that Fe-Oxides were formed. SEM analysis showed that bead morphology was characterized by a non-porous, smooth surface. In addition, viscosity showed extremely high viscosity at low shear rates, indicating a highly structured, viscoelastic soft solid. Rheological frequency sweeps further demonstrated that G′ ≫ G″ across the entire frequency range, confirming the hydrogel comprised a predominantly elastic, solid-like network that remains stable over time. Methylene blue sorption experiments revealed that equilibrium was reached after approximately 45 min, with a maximum sorption yield of 86% obtained at 200 ppm methylene blue, whereas increasing the concentration to 500 ppm led to a decrease in sorption yield. The hydrogel beads were successfully reused for five consecutive adsorption–desorption cycles. Kinetic analysis showed that the pseudo-second-order model provided the best fit, and the adsorption isotherms were well described by both the Langmuir and Freundlich models.