Abstract
BACKGROUND: Biomaterials play an increasing role in intervertebral disc regeneration and require preclinical testing, typically performed using organ culture and in vitro models. Native human discs are limited, and animal models often fail to mimic human disc degeneration. Thus, enzymes like chondroitinase ABC (chABC) and papain are used to simulate degenerative tissue changes and enable biomaterial injection. In previous work, we characterized the biomechanical and morphological effects of papain, which forms cavities in the disc. In contrast, chABC does not form cavities, but its biomechanical effects remain insufficiently characterized. This study aims to evaluate the macroscopic and biomechanical effects of chABC-specifically, range of motion (ROM), neutral zone (NZ), and disc height-in a bovine organ culture model, and assess the distribution of an injected hydrogel, comparing the results to published papain data. METHODS: Four groups of fresh bovine tail segments were prepared (n ≥ 10) and three received injections of chABC, papain, or PBS, followed by 7 days of culture. For papain and PBS, published data were supplemented with new specimens. Complex simulated physiological loading was applied to diminish disc swelling. The maximum volume of a serum-albumin-hydrogel was injected into all four groups. ROM, NZ, and disc height were measured before and after enzyme treatment, loading, and injection. Post-injection, microCT scans visualized material distribution within the discs. RESULTS: ChABC increased ROM by up to 92.1%, NZ by up to 79.4%, and decreased disc height by 2.1 mm. Hydrogel injection decreased ROM and NZ but increased disc height in all groups while enzyme treatments allowed more hydrogel injection (0.6 mL for chABC). Exemplary scans showed cloud-like hydrogel spread for chABC and a round-shaped degradation defect for papain. CONCLUSIONS: The findings indicate that chABC better simulates disc degeneration, whereas papain better models nucleotomies, and both enzymes preserve annulus integrity-providing valuable models for biomechanical testing.