AI Article Synopsis
- Meniscus injuries are common in sports and contribute to osteoarthritis, highlighting the need for effective reconstruction methods.
- Current substitutes fail to mimic the natural meniscus's structure and function, prompting the development of a new tissue-engineered meniscus (TEM) with a unique microstructure.
- This innovation promotes proper stem cell differentiation and mimics the biomechanical properties of natural meniscus, showing promising results in healing and joint preservation after implantation in animal models.
Article Abstract
Meniscus injury is one of the most common sports injuries within the knee joint, which is also a crucial pathogenic factor for osteoarthritis (OA). The current meniscus substitution products are far from able to restore meniscal biofunctions due to the inability to reconstruct the gradient heterogeneity of natural meniscus from biological and biomechanical perspectives. Here, inspired by the topology self-induced effect and native meniscus microstructure, we present an innovative tissue-engineered meniscus (TEM) with a unique gradient-sized diamond-pored microstructure (GSDP-TEM) through dual-stage temperature control 3D-printing system based on the mechanical/biocompatibility compatible high M poly(ε-caprolactone) (PCL). Biologically, the unique gradient microtopology allows the seeded mesenchymal stem cells with spatially heterogeneous differentiation, triggering gradient transition of the extracellular matrix (ECM) from the inside out. Biomechanically, GSDP-TEM presents excellent circumferential tensile modulus and load transmission ability similar to the natural meniscus. After implantation in rabbit knee, GSDP-TEM induces the regeneration of biomimetic heterogeneous neomeniscus and efficiently alleviates joint degeneration. This study provides an innovative strategy for functional meniscus reconstruction. Topological self-induced cell differentiation and biomechanical property also provides a simple and effective solution for other complex heterogeneous structure reconstructions in the human body and possesses high clinical translational potential.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10944202 | PMC |
| http://dx.doi.org/10.1016/j.bioactmat.2024.03.005 | DOI Listing |
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