A bioactive hydrogel harnessing the regenerative potential of notochordal cells serves as instructive cell carrier for nucleus pulposus repair

Publication date

2026-05-01

Authors

Laagland, Lisanne T.
Salzer, Elias
Fabra, Georgina Targa
Tong, Xiaole
Poramba-Liyanage, Deepani W.L.
Warin, Julie
Joyce, Kieran
Snuggs, Joseph
Riemers, Frank M.ORCID 0000-0003-4732-9447ISNI 0000000419473190
Utomo, LizetteORCID 0000-0003-2214-2344ISNI 0000000493069233

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Advisors

Supervisors

Document Type

Article
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taverne

Abstract

Natural biomatrices are popular owing to their ability to mimic tissue-specific biological properties. These properties are crucial for the intervertebral disc, a particularly demanding tissue whose degeneration is a major cause of chronic lower back pain. Degeneration starting within the core of the disc, the nucleus pulposus (NP), is marked by the loss of notochordal cells (NCs) and associated healthy extracellular matrix. The regulative potential of the NC-secretome was exploited through a PEG-based hydrogel formulated with decellularized porcine notochordal cell matrix (dNCM). Even under conditions which mimic the degenerate niche, the hydrogel supported maintenance of the phenotype of native porcine NCs, well-known for the difficulty in preserving their vacuolated morphology. dNCM-PEG hydrogel carrying human mesendodermal progenitors (hMEPCs; iPS-derived and capable of differentiating into NCs), was injected into NP explants with enzymatically induced matrix degradation and subjected to dynamical loading. hMEPCs engrafted successfully and a healthy disc cell phenotype was observed. Injection of dNCM + hMEPCs into degenerated discs in a pilot experimental dog study indicated that ∼7 % of the 0.5 million hMEPCs engrafted. Single cell RNAseq analysis showed over 30 % of the engrafted and recovered hMEPCs co-expressed Collagen Type II and Aggrecan consistent with a functional phenotype. No tumorigenic or systemic immunogenic side effects were observed. At the tissue level, TBXT expression, as well as matrix quality, were enhanced in the treated degenerate disc tissues. Together, this study highlights the translational potential of combining cell-based therapies with a bioactive material containing part of the NC secretome, warranting further development and validation.

Keywords

Bioactive materials, Bioreactors, Explant culture, Induced pluripotent stem cells, Low back pain, Regeneration, Ceramics and Composites, Biophysics, Bioengineering, Biomaterials, Mechanics of Materials, SDG 3 - Good Health and Well-being

Citation

Laagland, L T, Salzer, E, Fabra, G T, Tong, X, Poramba-Liyanage, D W L, Warin, J, Joyce, K, Snuggs, J, Riemers, F M, Utomo, L, Kamali, S A, Schmitz, T C, Vergara Vera, N S, Le Maitre, C L, Gantenbein, B, Meij, B P, Camus, A, Ito, K, Pandit, A & Tryfonidou, M A 2026, 'A bioactive hydrogel harnessing the regenerative potential of notochordal cells serves as instructive cell carrier for nucleus pulposus repair', Biomaterials, vol. 328, 123895, pp. 123895. https://doi.org/10.1016/j.biomaterials.2025.123895