Litcius/Paper detail

Total Meniscus Reconstruction Using a Polymeric Hybrid-Scaffold: Combined with 3D-Printed Biomimetic Framework and Micro-Particle

Hun‐Jin Jeong, Se‐Won Lee, Se-Won Lee, Myoung Wha Hong, Young‐Yul Kim, Kyoung Duck Seo, Young‐Sam Cho, Seung‐Jae Lee, Seung‐Jae Lee

2021Polymers16 citationsDOIOpen Access PDF

Abstract

The meniscus has poor intrinsic regenerative capability, and its injury inevitably leads to articular cartilage degeneration. Although there are commercialized off-the-shelf alternatives to achieve total meniscus regeneration, each has its own shortcomings such as individualized size matching issues and inappropriate mechanical properties. We manufactured a polycaprolactone-based patient-specific designed framework via a Computed Tomography scan images and 3D-printing technique. Then, we completed the hybrid-scaffold by combining the 3D-printed framework and mixture micro-size composite which consists of polycaprolactone and sodium chloride to create a cell-friendly microenvironment. Based on this hybrid-scaffold with an autograft cell source (fibrochondrocyte), we assessed mechanical and histological results using the rabbit total meniscectomy model. At postoperative 12-week, hybrid-scaffold achieved neo-meniscus tissue formation, and its shape was maintained without rupture or break away from the knee joint. Histological and immunohistochemical analysis results showed obvious ingrowth of the fibroblast-like cells and chondrocyte cells as well as mature lacunae that were embedded in the extracellular matrix. Hybrid-scaffolding resulted in superior shape matching as compared to original meniscus tissue. Histological analysis showed evidence of extensive neo-meniscus cell ingrowth. Additionally, the hybrid-scaffold did not induce osteoarthritis on the femoral condyle surface. The 3D-printed hybrid-scaffold may provide a promising approach that can be applied to those who received total meniscal resection, using patient-specific design and autogenous cell source.

Topics & Concepts

ScaffoldMeniscusMaterials sciencePolycaprolactoneBiomedical engineeringCartilageTissue engineeringOsteoarthritisFibrocartilageExtracellular matrix3d printedRegeneration (biology)Composite materialChemistryAnatomyMedicinePathologyPolymerArticular cartilageBiologyPhysicsIncidence (geometry)Cell biologyBiochemistryOpticsAlternative medicineKnee injuries and reconstruction techniquesTotal Knee Arthroplasty OutcomesBone Tissue Engineering Materials