PEER-REVIEWED PUBLICATION

2023

Photo-Cross-Linkable, Injectable, and Highly Adhesive GelMA-Glycol Chitosan Hydrogels for Cartilage Repair

A tensile test divider icon

Paul S, Schrobback K, et al.

Advanced Healthcare Materials

Queensland University of Technology, Bangabandhu Sheikh Mujibur Rahman Agricultural University, Gelomics Pty Ltd

RESEARCH SUMMARY
This study developed a photo-cross-linkable, injectable GelMA–glycol chitosan (GelMA-GC) hydrogel designed to achieve strong adhesion to native cartilage while supporting chondrocyte viability and matrix regeneration. The hydrogel system exhibited rapid visible-light crosslinking, tunable mechanical properties, and enhanced adhesive integration within cartilage defects. Mechanical testing demonstrated that GelMA-GC hydrogels achieved significantly higher interfacial strength and stiffness compared to GelMA alone, while maintaining cytocompatibility and promoting extracellular matrix deposition. In vitro and ex vivo cartilage defect models confirmed improved mechanical stability and tissue integration, highlighting the potential of GelMA-GC hydrogels as bioadhesive scaffolds for cartilage repair.
CellScale hexagons, without text

CELLSCALE INSTRUMENT USED

MicroTester

Microindentation-based mechanical characterization of cartilage–hydrogel constructs was performed using a CellScale high-precision, piezoelectric actuator-controlled microcompression system. Constructs were tested submerged in a temperature-controlled PBS bath at 37 °C. A spherical indenter (0.5 mm zirconium oxide bead) mounted on a cantilevered microbeam was positioned above the sample center and driven at a constant jogging speed (reported as 4 µm/s). The system continuously quantified indentation force and indentation depth by optically tracking microbeam deflection while controlling z-displacement via the piezo actuator. Samples were subjected to cyclic compression (three cycles) with force amplitude corresponding to ~10% of sample height, using 30 s loading and 30 s recovery phases per cycle (no rest between phases). Force–indentation data were then fit to a Hertz spherical contact model to calculate elastic modulus of the hydrogel construct under hydrated, physiologic-temperature conditions.
AUTHORS

Sattwikesh Paul, Karsten Schrobback, Phong Anh Tran, Christoph Meinert, Jordan William Davern, Angus Weekes, Travis Jacob Klein.

PUBLICATION DETAILS
JOURNAL

Advanced Healthcare Materials

YEAR

2023

INSTITUTIONS

Queensland University of Technology, Bangabandhu Sheikh Mujibur Rahman Agricultural University, Gelomics Pty Ltd

COUNTRIES

Australia, Bangladesh

INSTRUMENT USED

MicroTester

TESTING METHODS

Hydrated and Temperature Controlled TestingIndentation TestingMicro-Mechanical TestingViscoelastic & Time-Dependent Testing

RESEARCH APPLICATIONS

Cartilage and Meniscus MechanicsCell Laden HydrogelsECM & Decellularized Matrix MechanicsHydrogel Mechanical TestingInjectable & Regenerative Biomaterials

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