Human Osteochondral Granular Extracellular Matrix (gECM) Hydrogels Drive Tissue-Specific Composition and Mechanics

Authors

Heye, J., Schneider, S. E., Gallagher, K., Blanco, S., Barthold, J., McCabe, M. C., Maroney, S., Hansen, K. C., Floren, M., Neu, C.

Abstract

Osteochondral defects remain a major clinical challenge due to the limited regenerative capacity of cartilage and the complexity of the osteochondral interface. Here, we present a human-derived granular extracellular matrix (gECM) hydrogel platform designed for translational osteochondral repair. Using otherwise discarded human donor tissues, we developed cartilage and bone gECM hydrogels under current good manufacturing practice workflows. These materials are shear-thinning, immediately hold their form, and crosslink under physiological conditions to form stable constructs. Proteomic analysis confirmed that cartilage and bone gECM retain distinct tissue-specific biochemical signatures, while mechanical characterization demonstrated tissue-relevant stiffness, with bone gECM hydrogels exhibiting greater stiffness than cartilage gECM hydrogel. Particle packing density primarily governed viscosity, whereas tissue type contributed strongly to bulk stiffness. Together, these findings establish a scalable, human-derived gECM platform that integrates tissue-specific structural and mechanical cues, and advances a clinically translatable strategy for osteochondral repair.

Preprint server: bioRxiv
The authors list and abstract were imported from bioRxiv on 10 Jun 2026.

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