Viscoelastic Analysis of Pectin Hydrogels Regenerated from Citrus Pomelo Waste by Gelling Effects of Calcium Ion Crosslinking at Different pHs

Pectin was extracted from citrus pomelo waste, and the effects of calcium ions (Ca²⁺) on the gelation and hydrogels properties were investigated over a pH range of 3.2–8 by using viscoelastic analysis. The gelatinization of Ca²⁺-pectin was examined at concentrations of 0.9, 1.8, 2.4, and 3.6 M of Ca²⁺ in aqueous pectin solutions of 1%, 2%, 3%, and 4%. The gel transition of Ca²⁺-pectin solution to hydrogels was determined by measuring the storage modulus (G’) and loss modulus (G”) under mechanical strain from 0.01 to 100%. In a hydrogel of 3% pectin at Ca²⁺ = 2.4 M, as pH increased to 7, the G’ at 0.01 strain % was 3 × 10⁴ Pa, and 3 × 10³ Pa at pH 5, indicating that the crosslinking weakened at acidic pH. Due to the crosslinking between the calcium ions and the ionized carboxylic acid groups of pectin, the resulting hydrogel became stiff. When the mechanical strain % was in the range of 0.01–1%, G’ was unchanged and G” was an order of magnitude smaller than G’, indicating that the mechanical stress was relieved by the gel. In the range of 1–100%, the gel deformation progressed and both the moduli values were dropped. Collapse from the gel state to the solution state occurred at 1–10 strain %, but the softer hydrogels with G’ of 10³ Pa had a larger strain % than the stiffer hydrogels with G’ of 10⁴ Pa.