Antioxidant-biocompatible and stable catalase-based gelatin–alginate hydrogel scaffold with thermal wound healing capability: immobilization and delivery approach

• Published in: 3 Biotech Vol. 12; no. 3; p. 73
• Main Authors: Abdel-Mageed, Heidi Mohamed, Abd El Aziz, Amira Emad, Abdel Raouf, Batoul Mohamed, Mohamed, Saleh Ahmed, Nada, Dina
• Format: Journal Article
• Language: English
• Published: Cham Springer International Publishing 01.03.2022; Springer Nature B.V
• Subjects: Agriculture; Alginates; Alginic acid; Antioxidants; Biocompatibility; Bioinformatics; Biomaterials; Biomedical materials; Biopolymers; Biotechnology; Calcium chloride; Cancer Research; Catalase; Chemistry; Chemistry and Materials Science; Entrapment; Gelatin; Hydrogels; Hydrogen peroxide; Immobilization; Original; Original Article; Prolongation; Reactive oxygen species; Scavenging; Statistical analysis; Stem Cells; Thermal injury; Thermal stability; Wound healing; Stabilization; Thermal injury; Gelatin alginate biopolymers; Half-life; Hydrogel; Catalase immobilization; Burn wound healing
• ISSN: 2190-572X; 2190-5738
• DOI: 10.1007/s13205-022-03131-4

Hydrogel-based matrix prepared using biopolymers is a new frontier of emerging platforms for enzyme immobilization for biomedical applications. Catalase (CAT) delivery can be effective in inhibiting reactive oxygen species (ROS)-mediated prolongation of the wound healing process. In this study, to improve CAT stability for effective application, gelatin(Gel)–alginate (Alg) biocompatible hydrogel (Gel–Alg), as immobilization support, was prepared using calcium chloride as an ionic cross-linker. High entrapment efficiency of 92% was obtained with 2% Gel and 1.5% Alg. Hydrogel immobilized CAT (CAT–Gel–Alg) showed a wide range of pH from 4 to 9 and temperature stability between 20 to 60 °C, compared to free CAT. CAT–Gel–Alg kinetic parameters revealed an increased K m (24.15 mM) and a decreased V max (1.39 µmol H 2 O 2 /mg protein min) × 10 4 . CAT–Gel–Alg retained 52% of its original activity after 20 consecutive catalytic runs and displayed improved thermal stability with a higher t 1/2 value (half-life of 100.43 vs. 46 min). In addition, 85% of the initial activity was maintained after 8 weeks’ storage at 4 °C. At 24 h after thermal injury, a statistically significant difference in lesion sizes between the treated group and the control group was reported. Finally, our findings suggest that the superior CAT–Gel–Alg stability and reusability are resonant features for efficient biomedical applications, and ROS scavenging by CAT in the post-burn phase offers protection for local treatment of burned tissues with encouraging wound healing kinetics.